Method for producing objective substance

ABSTRACT

A method for producing an objective substance such as vanillin and vanillic acid is provided. An objective substance is produced from a carbon source or a precursor of the objective substance by using a microorganism that is able to produce the objective substance, which microorganism has been modified so that the activity of an enzyme involved in SAM cycle (SAM cycle enzyme) is increased.

This application claims priority under 35 U.S.C. § 119 to U.S. Provisional Patent Application No. 62/591,910, filed Nov. 29, 2017, the entirety of which is incorporated by reference herein. Also, the Sequence Listing filed electronically herewith is hereby incorporated by reference (File name: 2018-11-26T_US-571_Seq_List; File size: 317 KB; Date recorded: 2018-11-26).

BACKGROUND OF THE INVENTION Field of the Invention

The present invention relates to a method for producing an objective substance such as vanillin and vanillic acid by using a microorganism.

Brief Description of the Related Art

Vanillin is a major ingredient that provides the smell of vanilla, and is used as an aromatic in foods, drinks, perfumes, and so forth. Vanillin is usually produced by extraction from natural products or by chemical synthesis.

Bioengineering techniques have also been tried in production of vanillin. For example, vanillin has been tried to be produced by using various microorganisms and raw materials, such as eugenol, isoeugenol, ferulic acid, glucose, vanillic acid, coconut husk, or the like (Kaur B. and Chakraborty D., Biotechnological and molecular approaches for vanillin production: a review. Appl Biochem Biotechnol. 2013 February; 169(4):1353-72). In addition, other methods for producing vanillin using bioengineering techniques include producing vanillin as a glycoside (WO2013/022881 and WO2004/111254), producing vanillin from ferulic acid by using vanillin synthase (JP2015-535181), producing vanillic acid by fermentation of Escherichia coli and then enzymatically converting vanillic acid into vanillin (U.S. Pat. No. 6,372,461).

S-adenosylmethionine (SAM) is regenerated via the SAM cycle, which is a methylation cycle. S-adenosyl-L-homocysteine hydrolase, methionine synthase, methionine adenosyltransferase, and 5,10-methylenetetrahydrofolate reductase are all involved in the SAM cycle.

S-adenosyl-L-homocysteine hydrolase catalyzes the hydrolysis of S-adenosyl-L-homocysteine (SAH) to generate L-homocysteine and adenosine. Examples of the S-adenosyl-L-homocysteine hydrolase include an SahH protein, which is encoded by an sahH gene.

Methionine synthase catalyzes the methylation of L-homocysteine to generate L-methionine in the presence of a methyl group donor. Examples of the methionine synthase include MetE and MetH proteins, which are encoded by metE and metH genes, respectively.

Methionine adenosyltransferase catalyzes the conversion of L-methionine into SAM in the presence of ATP. Examples of the methionine adenosyltransferase include an MetK protein, which is encoded by an metK gene.

5,10-methylenetetrahydrofolate reductase catalyzes the reduction of 5,10-methylenetetrahydrofolate to generate 5-methyltetrahydrofolate (5-MTHF) in the presence of an electron donor. Examples of the 5,10-methylenetetrahydrofolate reductase include an MetF protein, which is encoded by an metF gene.

SUMMARY OF THE INVENTION

The present invention describes a novel technique for improving production of an objective substance such as vanillin and vanillic acid, and thereby provides a method for efficiently producing the objective substance.

It is an aspect of the present invention that a microorganism is able to produce an objective substance such as vanillin and vanillic acid in a significantly improved manner by modifying the microorganism so that the activity of an enzyme involved in SAM cycle, such as a SAM cycle enzyme, is increased.

That is, it is an aspect of the present invention to provide a method for producing an objective substance, the method comprising:

producing the objective substance by using a microorganism having an ability to produce the objective substance,

wherein the microorganism has been modified so that the activity of an S-adenosylmethionine cycle enzyme is increased as compared with a non-modified strain,

wherein the S-adenosylmethionine cycle enzyme is selected from the group consisting of methionine adenosyltransferase, methionine synthase, 5,10-methylenetetrahydrofolate reductase, and combinations thereof, and

wherein the objective substance is selected from the group consisting of:

(X) metabolites the biosynthesis of which requires S-adenosylmethionine;

(Y) L-methionine; and

(Z) combinations thereof,

provided that the objective substance is selected from the metabolites (X) when only the activity of methionine adenosyltransferase is increased.

It is a further aspect of the present invention to provide the method as described above, wherein said producing comprises:

cultivating the microorganism in a culture medium containing a carbon source to produce and accumulate the objective substance in the culture medium.

It is a further aspect of the present invention to provide the method as described above, wherein said producing comprises:

converting a precursor of the objective substance into the objective substance by using the microorganism.

It is a further aspect of the present invention to provide the method as described above, wherein said using comprises:

cultivating the microorganism in a culture medium containing the precursor to produce and accumulate the objective substance in the culture medium.

It is a further aspect of the present invention to provide the method as described above, wherein said converting comprises:

allowing cells of the microorganism to act on the precursor in a reaction mixture to produce and accumulate the objective substance in the reaction mixture.

It is a further aspect of the present invention to provide the method as described above, wherein the cells are cells present in a culture broth of the microorganism, cells collected from the culture broth, cells present in a processed product of the culture broth, cells present in a processed product of the collected cells, or a combination of these.

It is a further aspect of the present invention to provide the method as described above, wherein the precursor is selected from the group consisting of protocatechuic acid, protocatechualdehyde, L-tryptophan, L-histidine, L-phenylalanine, L-tyrosine, L-arginine, L-ornithine, glycine, and combinations thereof.

It is a further aspect of the present invention to provide the method as described above, the method further comprising collecting the objective substance.

It is a further aspect of the present invention to provide the method as described above, wherein the methionine adenosyltransferase is encoded by an metK gene, the methionine synthase is encoded by an metH gene and/or an metE gene, and the 5,10-methylenetetrahydrofolate reductase is encoded by an metF gene.

It is a further aspect of the present invention to provide the method as described above, wherein:

the metK gene encodes a protein selected from the group consisting of:

(1a) a protein comprising the amino acid sequence of SEQ ID NO: 162,

(1b) a protein comprising the amino acid sequence of SEQ ID NO: 162 that includes substitution, deletion, insertion, and/or addition of 1 to 10 amino acid residues, and wherein said protein has methionine adenosyltransferase activity, and

(1c) a protein comprising an amino acid sequence having an identity of 90% or higher to the amino acid sequence of SEQ ID NO: 162, and wherein said protein has methionine adenosyltransferase activity;

the metH gene encodes a protein selected from the group consisting of:

(2a) a protein comprising the amino acid sequence of SEQ ID NO: 168 or 170,

(2b) a protein comprising the amino acid sequence of SEQ ID NO: 168 or 170 that includes substitution, deletion, insertion, and/or addition of 1 to 10 amino acid residues, and wherein said protein has methionine synthase activity, and

(2c) a protein comprising an amino acid sequence having an identity of 90% or higher to the amino acid sequence of SEQ ID NO: 168 or 170, and wherein said protein has methionine synthase activity;

the metE gene encodes a protein selected from the group consisting of:

(3a) a protein comprising the amino acid sequence of SEQ ID NO: 166,

(3b) a protein comprising the amino acid sequence of SEQ ID NO: 166 that includes substitution, deletion, insertion, and/or addition of 1 to 10 amino acid residues, and wherein said protein has methionine synthase activity, and

(3c) a protein comprising an amino acid sequence showing an identity of 90% or higher to the amino acid sequence of SEQ ID NO: 166, and wherein said protein has methionine synthase activity; and

the metF gene encodes a protein selected from the group consisting of:

(4a) a protein comprising the amino acid sequence of SEQ ID NO: 172, 174, or 184,

(4b) a protein comprising the amino acid sequence of SEQ ID NO: 172, 174, or 184 that includes substitution, deletion, insertion, and/or addition of 1 to 10 amino acid residues, and wherein said protein has 5,10-methylenetetrahydrofolate reductase activity, and (4c) a protein comprising an amino acid sequence having an identity of 90% or higher to the amino acid sequence of SEQ ID NO: 172, 174, or 184, and wherein said protein has 5,10-methylenetetrahydrofolate reductase activity.

It is a further aspect of the present invention to provide the method as described above, wherein the activity of the S-adenosylmethionine cycle enzyme is increased by increasing the expression of a gene encoding the S-adenosylmethionine cycle enzyme.

It is a further aspect of the present invention to provide the method as described above, wherein the expression of the gene encoding the S-adenosylmethionine cycle enzyme is increased by increasing the copy number of the gene and/or modifying an expression control sequence of the gene.

It is a further aspect of the present invention to provide the method as described above, wherein the microorganism is a bacterium belonging to the family Enterobacteriaceae, a coryneform bacterium, or yeast.

It is a further aspect of the present invention to provide the method as described above, wherein the microorganism is a bacterium belonging to the genus Corynebacterium.

It is a further aspect of the present invention to provide the method as described above, wherein the microorganism is Corynebacterium glutamicum.

It is a further aspect of the present invention to provide the method as described above, wherein the microorganism is a bacterium belonging to the genus Escherichia.

It is a further aspect of the present invention to provide the method as described above, wherein the microorganism is Escherichia coli.

It is a further aspect of the present invention to provide the method as described above, wherein the metabolites (X) are selected from the group consisting of vanillin, vanillic acid, melatonin, ergothioneine, mugineic acid, ferulic acid, polyamine, guaiacol, 4-vinylguaiacol, 4-ethylguaiacol, creatine, and combinations thereof.

It is a further aspect of the present invention to provide the method as described above, wherein the microorganism has been further modified so that the activity of an enzyme that is involved in the biosynthesis of the objective substance is increased as compared with a non-modified strain.

It is a further aspect of the present invention to provide the method as described above, wherein the enzyme that is involved in the biosynthesis of the objective substance is selected from the group consisting of 3-deoxy-D-arabino-heptulosonic acid 7-phosphate synthase, 3-dehydroquinate synthase, 3-dehydroquinate dehydratase, 3-dehydroshikimate dehydratase, O-methyltransferase, aromatic aldehyde oxidoreductase, and combinations thereof.

It is a further aspect of the present invention to provide the method as described above, wherein the microorganism has been further modified so that the activity of phosphopantetheinyl transferase is increased as compared with a non-modified strain.

It is a further aspect of the present invention to provide the method as described above, wherein the microorganism has been further modified so that the activity of an enzyme that is involved in the by-production of a substance other than the objective substance is reduced as compared with a non-modified strain.

It is a further aspect of the present invention to provide the method as described above, wherein the enzyme that is involved in the by-production of a substance other than the objective substance is selected from the group consisting of vanillate demethylase, protocatechuate 3,4-dioxygenase, alcohol dehydrogenase, shikimate dehydrogenase, and combinations thereof.

It is a further aspect of the present invention to provide the method as described above, wherein the microorganism has been further modified so that the activity of an L-cysteine biosynthesis enzyme is increased as compared with a non-modified strain.

It is a further aspect of the present invention to provide the method as described above, wherein the L-cysteine biosynthesis enzyme is selected from the group consisting of proteins encoded by a cysI gene, cysX gene, cysH gene, cysD gene, cysN gene, cysY gene, cysZ gene, fpr2 gene, and combinations thereof.

It is a further aspect of the present invention to provide the method as described above, wherein the activity of the L-cysteine biosynthesis enzyme is increased by increasing the activity of a protein encoded by a cysR gene.

It is a further aspect of the present invention to provide the method as described above, wherein the microorganism has been further modified so that the activity of a protein encoded by an NCgl2048 gene is reduced as compared with a non-modified strain.

It is a further aspect of the present invention to provide the method as described above, wherein the microorganism has been further modified so that the activity of enolase is reduced as compared with a non-modified strain.

It is a further aspect of the present invention to provide the method as described above, wherein the microorganism has been further modified so that the activity of L-serine deaminase is reduced as compared with a non-modified strain.

It is a further aspect of the present invention to provide the method as described above, wherein the microorganism has been further modified so that the activity of AICAR formyltransferase/IMP cyclohydrolase is reduced as compared with a non-modified strain and/or so that a gene encoding AICAR formyltransferase/IMP cyclohydrolase has a mutation for improving the ability of the microorganism to produce the objective substance.

It is a further aspect of the present invention to provide the method as described above, wherein the activity of AICAR formyltransferase/IMP cyclohydrolase is reduced by modifying a gene encoding AICAR formyltransferase/IMP cyclohydrolase so as to have a mutation for improving the ability of the microorganism to produce the objective substance.

It is a further aspect of the present invention to provide the method as described above, wherein the mutation for improving the ability of the microorganism to produce the objective substance is a mutation replacing the serine residue at position 37 of the encoded AICAR formyltransferase/IMP cyclohydrolase with another amino acid residue.

It is a further aspect of the present invention to provide the method as described above, wherein said another amino acid residue is a phenylalanine residue.

It is a further aspect of the present invention to provide a method for producing vanillin, the method comprising:

producing vanillic acid by the method as described above; and

converting said vanillic acid to vanillin.

DETAILED DESCRIPTION OF THE EXEMPLARY EMBODIMENTS

<1> Microorganism

The microorganism as described herein is a microorganism having an ability to produce an objective substance, which microorganism has been modified so that the activity of an SAM cycle enzyme is increased. The ability to produce an objective substance can also be referred to as an “objective substance-producing ability”.

<1-1> Microorganism Having Objective Substance-Producing Ability

The phrase “microorganism having an objective substance-producing ability” can refer to a microorganism that is able to produce an objective substance.

The phrase “microorganism having an objective substance-producing ability” can refer to a microorganism that is able to produce an objective substance by fermentation, if the microorganism is used in a fermentation method. That is, the phrase “microorganism having an objective substance-producing ability” can refer to a microorganism that is able to produce an objective substance from a carbon source. Specifically, the phrase “microorganism having an objective substance-producing ability” can refer to a microorganism that is able to, upon being cultured in a culture medium, such as a culture medium containing a carbon source, produce and accumulate the objective substance in the culture medium to such a degree that the objective substance can be collected from the culture medium.

Also, the phrase “microorganism having an objective substance-producing ability” can refer to a microorganism that is able to produce an objective substance by bioconversion, if the microorganism is used in a bioconversion method. That is, the phrase “microorganism having an objective substance-producing ability” can refer to a microorganism that is able to produce an objective substance from a precursor of the objective substance. Specifically, the phrase “microorganism having an objective substance-producing ability” can refer to a microorganism that is able to, upon being cultured in a culture medium containing a precursor of an objective substance, produce and accumulate the objective substance in the culture medium to such a degree that the objective substance can be collected from the culture medium. Also, specifically, the phrase “microorganism having an objective substance-producing ability” can refer to a microorganism that is able to, upon being allowed to act on a precursor of an objective substance in a reaction mixture, produce and accumulate the objective substance in the reaction mixture to such a degree that the objective substance can be collected from the reaction mixture.

The microorganism having an objective substance-producing ability can be able to produce and accumulate the objective substance in the culture medium or reaction mixture in an amount larger than that can be obtained with a non-modified strain. A non-modified strain can also be referred to as a “strain of a non-modified microorganism” or a “non-modified microorganism”. The term “non-modified strain” or “strain of a non-modified microorganism” can refer to a control strain that has not been modified so that the activity of an SAM cycle enzyme is increased. The microorganism having an objective substance-producing ability can be able to accumulate the objective substance in the culture medium or reaction mixture in an amount of, for example, 0.01 g/L or more, 0.05 g/L or more, or 0.09 g/L or more.

The objective substance can be selected from L-methionine and metabolites the biosynthesis of which requires S-adenosylmethionine (SAM). Examples of the metabolites the biosynthesis of which requires SAM can include, for example, vanillin, vanillic acid, melatonin, ergothioneine, mugineic acid, ferulic acid, polyamine, guaiacol, 4-vinylguaiacol, 4-ethylguaiacol, and creatine. Examples of polyamine can include spermidine and spermine. The combination of the SAM cycle enzyme and the objective substance is not particularly limited, so long as the increased activity of the SAM cycle enzyme in a microorganism results in increased production of the objective substance. For example, when methionine adenosyltransferase is used alone as the SAM cycle enzyme, or when used in combination with other SAM cycle enzyme(s), the objective substance may be metabolites the biosynthesis of which requires SAM, that is, L-methionine may not be produced as the objective substance. Alternatively, for example, when methionine adenosyltransferase is not used as the SAM cycle enzyme, for example, when S-adenosyl-L-homocysteine hydrolase, methionine synthase, 5,10-methylenetetrahydrofolate reductase, or a combination of these is used, the objective substance may be L-methionine and/or the metabolites of which the biosynthesis requires SAM, that is, L-methionine may be produced as the objective substance. The microorganism as described herein may be able to produce only one kind of objective substance, or may have an ability to produce two or more kinds of objective substances. Also, the microorganism may be able to produce an objective substance from one kind of precursor of the objective substance or from two or more kinds of precursors of the objective substance.

When the objective substance is a compound that can form a salt, the objective substance may be obtained as a free compound, a salt thereof, or a mixture of these. That is, the term “objective substance” can refer to an objective substance in a free form, a salt thereof, or a mixture thereof, unless otherwise stated. Examples of the salt can include, for example, sulfate salt, hydrochloride salt, carbonate salt, ammonium salt, sodium salt, and potassium salt. As the salt of the objective substance, one kind of salt may be employed, or two or more kinds of salts may be employed in combination.

A microorganism that can be used as a parent strain to construct the microorganism as described herein is not particularly limited. Examples of the microorganism can include bacteria and yeast.

Examples of the bacteria can include bacteria belonging to the family Enterobacteriaceae and coryneform bacteria.

Examples of bacteria belonging to the family Enterobacteriaceae can include bacteria belonging to the genus Escherichia, Enterobacter, Pantoea, Klebsiella, Serratia, Envinia, Photorhabdus, Providencia, Salmonella, Morganella, or the like. Specifically, bacteria classified into the family Enterobacteriaceae according to the taxonomy used in the NCBI (National Center for Biotechnology Information) database (ncbi.nlm.nih.gov/Taxonomy/Browser/wwwtax.cgi?id=91347) can be used.

The Escherichia bacteria are not particularly limited, and examples thereof can include those classified into the genus Escherichia according to the taxonomy known to those skilled in the field of microbiology. Examples of the Escherichia bacteria can include, for example, those described in the work of Neidhardt et al. (Backmann B. J., 1996, Derivations and Genotypes of some mutant derivatives of Escherichia coli K-12, pp. 2460-2488, Table 1, In F. D. Neidhardt (ed.), Escherichia coli and Salmonella Cellular and Molecular Biology/Second Edition, American Society for Microbiology Press, Washington, D.C.). Examples of the Escherichia bacteria can include, for example, Escherichia coli. Specific examples of Escherichia coli can include, for example, Escherichia coli K-12 strains such as W3110 strain (ATCC 27325) and MG1655 strain (ATCC 47076); Escherichia coli K5 strain (ATCC 23506); Escherichia coli B strains such as BL21 (DE3) strain; and derivative strains thereof.

The Enterobacter bacteria are not particularly limited, and examples can include those classified into the genus Enterobacter according to the taxonomy known to those skilled in the field of microbiology. Examples of the Enterobacter bacterium can include, for example, Enterobacter agglomerans and Enterobacter aerogenes. Specific examples of Enterobacter agglomerans can include, for example, the Enterobacter agglomerans ATCC 12287 strain. Specific examples of Enterobacter aerogenes can include, for example, the Enterobacter aerogenes ATCC 13048 strain, NBRC 12010 strain (Biotechnol. Bioeng., 2007, Mar. 27; 98(2):340-348), and AJ110637 strain (FERM BP-10955). Examples of the Enterobacter bacteria can also include, for example, the strains described in European Patent Application Laid-open (EP-A) No. 0952221. In addition, Enterobacter agglomerans can also include some strains classified as Pantoea agglomerans.

The Pantoea bacteria are not particularly limited, and examples can include those classified into the genus Pantoea according to the taxonomy known to those skilled in the field of microbiology. Examples of the Pantoea bacteria can include, for example, Pantoea ananatis, Pantoea stewartii, Pantoea agglomerans, and Pantoea citrea. Specific examples of Pantoea ananatis can include, for example, the Pantoea ananatis LMG20103 strain, AJ13355 strain (FERM BP-6614), AJ13356 strain (FERM BP-6615), AJ13601 strain (FERM BP-7207), SC17 strain (FERM BP-11091), SC17(0) strain (VKPM B-9246), and SC17sucA strain (FERM BP-8646). Some of Enterobacter bacteria and Envinia bacteria were reclassified into the genus Pantoea (Int. J. Syst. Bacteriol., 39, 337-345 (1989); Int. J. Syst. Bacteriol., 43, 162-173 (1993)). For example, some strains of Enterobacter agglomerans were recently reclassified into Pantoea agglomerans, Pantoea ananatis, Pantoea stewartii, or the like on the basis of nucleotide sequence analysis of 16S rRNA etc. (Int. J. Syst. Bacteriol., 39, 337-345 (1989)). The Pantoea bacteria can include those reclassified into the genus Pantoea as described above.

Examples of the Envinia bacteria can include Envinia amylovora and Envinia carotovora. Examples of the Klebsiella bacteria can include Klebsiella planticola.

Examples of coryneform bacteria can include bacteria belonging to the genus Corynebacterium, Brevibacterium, Microbacterium, or the like.

Specific examples of such coryneform bacteria can include the following species.

Corynebacterium acetoacidophilum

Corynebacterium acetoglutamicum

Corynebacterium alkanolyticum

Corynebacterium callunae

Corynebacterium crenatum

Corynebacterium glutamicum

Corynebacterium lilium

Corynebacterium melassecola

Corynebacterium thermoaminogenes (Corynebacterium efficiens)

Corynebacterium herculis

Brevibacterium divaricatum (Corynebacterium glutamicum)

Brevibacterium flavum (Corynebacterium glutamicum)

Brevibacterium immariophilum

Brevibacterium lactofermentum (Corynebacterium glutamicum)

Brevibacterium roseum

Brevibacterium saccharolyticum

Brevibacterium thiogenitalis

Corynebacterium ammoniagenes (Corynebacterium stationis)

Brevibacterium album

Brevibacterium cerinum

Microbacterium ammoniaphilum

Specific examples of the coryneform bacteria can include the following strains.

Corynebacterium acetoacidophilum ATCC 13870

Corynebacterium acetoglutamicum ATCC 15806

Corynebacterium alkanolyticum ATCC 21511

Corynebacterium callunae ATCC 15991

Corynebacterium crenatum AS1.542

Corynebacterium glutamicum ATCC 13020, ATCC 13032, ATCC 13060, ATCC 13869, FERM BP-734

Corynebacterium lilium ATCC 15990

Corynebacterium melassecola ATCC 17965

Corynebacterium efficiens (Corynebacterium thermoaminogenes) AJ12340 (FERM BP-1539)

Corynebacterium herculis ATCC 13868

Brevibacterium divaricatum (Corynebacterium glutamicum) ATCC 14020

Brevibacterium flavum (Corynebacterium glutamicum) ATCC 13826, ATCC 14067, AJ12418 (FERM BP-2205)

Brevibacterium immariophilum ATCC 14068

Brevibacterium lactofermentum (Corynebacterium glutamicum) ATCC 13869

Brevibacterium roseum ATCC 13825

Brevibacterium saccharolyticum ATCC 14066

Brevibacterium thiogenitalis ATCC 19240

Corynebacterium ammoniagenes (Corynebacterium stationis) ATCC 6871, ATCC 6872

Brevibacterium album ATCC 15111

Brevibacterium cerinum ATCC 15112

Microbacterium ammoniaphilum ATCC 15354

The coryneform bacteria can include bacteria that had previously been classified into the genus Brevibacterium, but are now united into the genus Corynebacterium (Int. J. Syst. Bacteriol., 41, 255 (1991)). Moreover, Corynebacterium stationis can include bacteria that had previously been classified as Corynebacterium ammoniagenes, but are now re-classified into Corynebacterium stationis on the basis of nucleotide sequence analysis of 16S rRNA etc. (Int. J. Syst. Evol. Microbiol., 60, 874-879 (2010)).

The yeast may be budding or fission yeast. The yeast may be haploid, diploid, or more polyploid yeast. Examples of the yeast can include yeast belonging to the genus Saccharomyces such as Saccharomyces cerevisiae, the genus Pichia (also referred to as the genus Wickerhamomyces) such as Pichia ciferrii, Pichia sydowiorum, and Pichia pastoris, the genus Candida such as Candida utilis, the genus Hansenula such as Hansenula polymorpha, and the genus Schizosaccharomyces such as Schizosaccharomyces pombe.

These strains are available from, for example, the American Type Culture Collection (Address: P.O. Box 1549, Manassas, Va. 20108, United States of America, or atcc.org). That is, registration numbers are given to the respective strains, and the strains can be ordered using these registration numbers (refer to atcc.org). The registration numbers of the strains are listed in the catalogue of the American Type Culture Collection. These strains can also be obtained from, for example, the depositories at which the strains were deposited.

The microorganism may inherently have an objective substance-producing ability, or may have been modified so that it has an objective substance-producing ability. The microorganism having an objective substance-producing ability can be obtained by imparting an objective substance-producing ability to such a microorganism as mentioned above, or enhancing an objective substance-producing ability of such a microorganism as mentioned above.

Hereafter, specific examples of the methods for imparting or enhancing an objective substance-producing ability will be explained. Such modifications as exemplified below for imparting or enhancing an objective substance-producing ability may be employed independently, or may be used in an appropriate combination.

An objective substance can be generated by the action of an enzyme that is involved in the biosynthesis of the objective substance. Such an enzyme can also be referred to as “objective substance biosynthesis enzyme”. Therefore, the microorganism may have an objective substance biosynthesis enzyme. In other words, the microorganism may have a gene encoding an objective substance biosynthesis enzyme. Such a gene can also be referred to as “objective substance biosynthesis gene”. The microorganism may inherently have an objective substance biosynthesis gene, or may have been introduced with an objective substance biosynthesis gene. The methods for introducing a gene will be explained herein.

Also, an objective substance-producing ability of a microorganism can be improved by increasing the activity of an objective substance biosynthesis enzyme. That is, examples of the methods for imparting or enhancing an objective substance-producing ability can include a method of increasing the activity of an objective substance biosynthesis enzyme. That is, the microorganism may have been modified so that the activity of an objective substance biosynthesis enzyme is increased. The activity of one kind of objective substance biosynthesis enzyme may be increased, or the activities of two or more kinds of objective substance biosynthesis enzymes may be increased. The method for increasing the activity of a protein, such as an enzyme etc., will be described herein. The activity of a protein, such as an enzyme etc., can be increased by, for example, increasing the expression of a gene encoding the protein.

An objective substance can be generated from, for example, a carbon source and/or a precursor of the objective substance. Hence, examples of the objective substance biosynthesis enzyme can include, for example, enzymes that catalyze the conversion of the carbon source and/or the precursor into the objective substance. For example, 3-dehydroshikimic acid can be produced via a part of shikimate pathway, which may include steps catalyzed by 3-deoxy-D-arabino-heptulosonic acid 7-phosphate synthase (DAHP synthase), 3-dehydroquinate synthase, and 3-dehydroquinate dehydratase; 3-dehydroshikimic acid can be converted to protocatechuic acid by the action of 3-dehydroshikimate dehydratase (DHSD); protocatechuic acid can be converted to vanillic acid or protocatechualdehyde by the action of O-methyltransferase (OMT) or aromatic aldehyde oxidoreductase (also referred to as aromatic carboxylic acid reductase; ACAR), respectively; and vanillic acid or protocatechualdehyde can be converted to vanillin by the action of ACAR or OMT, respectively. That is, specific examples of the objective substance biosynthesis enzyme can include, for example, DAHP synthase, 3-dehydroquinate synthase, 3-dehydroquinate dehydratase, DHSD, OMT, and ACAR.

The term “3-deoxy-D-arabino-heptulosonic acid 7-phosphate synthase (DAHP synthase)” can refer to a protein that has the activity of catalyzing the reaction of converting D-erythrose 4-phosphate and phosphoenolpyruvic acid into 3-deoxy-D-arabino-heptulosonate 7-phosphate (DAHP) and phosphate (EC 2.5.1.54). This activity can also be referred to as a “DAHP synthase activity”. A gene encoding a DAHP synthase can also be referred to as a “DAHP synthase gene”. Examples of a DAHP synthase can include AroF, AroG, and AroH proteins, which are encoded by aroF, aroG, and aroH genes, respectively. Among these, the AroG protein may function as the major DAHP synthase. Examples of a DAHP synthase such as the AroF, AroG, and AroH proteins can include those native to various organisms such as Enterobacteriaceae bacteria and coryneform bacteria. Specific examples of a DAHP synthase can include the AroF, AroG, and AroH proteins native to E. coli. The nucleotide sequence of the aroG gene native to the E. coli K-12 MG1655 strain is shown as SEQ ID NO: 1, and the amino acid sequence of the AroG protein encoded by this gene is shown as SEQ ID NO: 2.

The DAHP synthase activity can be measured by, for example, incubating the enzyme with substrates, such as D-erythrose 4-phosphate and phosphoenolpyruvic acid, and measuring the enzyme- and substrate-dependent generation of DAHP.

The term “3-dehydroquinate synthase” can refer to a protein that has the activity of catalyzing the reaction of dephosphorylating DAHP to generate 3-dehydroquinic acid (EC 4.2.3.4). This activity can also be referred to as a “3-dehydroquinate synthase activity”. A gene encoding a 3-dehydroquinate synthase can also be referred to as a “3-dehydroquinate synthase gene”. Examples of a 3-dehydroquinate synthase can include an AroB protein, which is encoded by an aroB gene. Examples of a 3-dehydroquinate synthase such as the AroB protein can include those native to various organisms such as Enterobacteriaceae bacteria and coryneform bacteria. Specific examples of a 3-dehydroquinate synthase can include the AroB protein native to E. coli. The nucleotide sequence of the aroB gene native to the E. coli K-12 MG1655 strain is shown as SEQ ID NO: 3, and the amino acid sequence of the AroB protein encoded by this gene is shown as SEQ ID NO: 4.

The 3-dehydroquinate synthase activity can be measured by, for example, incubating the enzyme with a substrate, such as DAHP, and measuring the enzyme- and substrate-dependent generation of 3-dehydroquinic acid.

The term “3-dehydroquinate dehydratase” can refer to a protein that has the activity of catalyzing the reaction of dehydrating 3-dehydroquinic acid to generate 3-dehydroshikimic acid (EC 4.2.1.10). This activity can also be referred to as a “3-dehydroquinate dehydratase activity”. A gene encoding a 3-dehydroquinate dehydratase can also be referred to as a “3-dehydroquinate dehydratase gene”. Examples of a 3-dehydroquinate dehydratase can include an AroD protein, which is encoded by an aroD gene. Examples of a 3-dehydroquinate dehydratase such as the AroD protein can include those native to various organisms such as Enterobacteriaceae bacteria and coryneform bacteria. Specific examples of a 3-dehydroquinate dehydratase can include the AroD protein native to E. coli. The nucleotide sequence of the aroD gene native to the E. coli K-12 MG1655 strain is shown as SEQ ID NO: 5, and the amino acid sequence of the AroD protein encoded by this gene is shown as SEQ ID NO: 6.

The 3-dehydroquinate dehydratase activity can be measured by, for example, incubating the enzyme with a substrate, such as 3-dehydroquinic acid, and measuring the enzyme- and substrate-dependent generation of 3-dehydroshikimic acid.

The term “3-dehydroshikimate dehydratase (DHSD)” can refer to a protein that has the activity of catalyzing the reaction of dehydrating 3-dehydroshikimic acid to generate protocatechuic acid (EC 4.2.1.118). This activity can also be referred to as a “DHSD activity”. A gene encoding a DHSD can also be referred to as a “DHSD gene”. Examples of a DHSD can include an AsbF protein, which is encoded by an asbF gene. Examples of a DHSD such as the AsbF protein can include those native to various organisms such as Bacillus thuringiensis, Neurospora crassa, and Podospora pauciseta. The nucleotide sequence of the asbF gene native to the Bacillus thuringiensis BMB171 strain is shown as SEQ ID NO: 7, and the amino acid sequence of the AsbF protein encoded by this gene is shown as SEQ ID NO: 8.

The DHSD activity can be measured by, for example, incubating the enzyme with a substrate, such as 3-dehydroshikimic acid, and measuring the enzyme- and substrate-dependent generation of protocatechuic acid.

The expression of a gene encoding an enzyme of the shikimate pathway, such as a DAHP synthase, 3-dehydroquinate synthase, and 3-dehydroquinate dehydratase, is repressed by the tyrosine repressor TyrR, which is encoded by a tyrR gene. Therefore, the activity of an enzyme of the shikimate pathway can also be increased by reducing the activity of the tyrosine repressor TyrR. Examples of the tyrosine repressor TyrR can include those native to various organisms such as Enterobacteriaceae bacteria and coryneform bacteria. Specific examples of the tyrosine repressor TyrR can include the TyrR protein native to E. coli. The nucleotide sequence of the tyrR gene native to the E. coli K-12 MG1655 strain is shown as SEQ ID NO: 9, and the amino acid sequence of the TyrR protein encoded by this gene is shown as SEQ ID NO: 10.

The term “O-methyltransferase (OMT)” can refer to a protein that has the activity of catalyzing the reaction of methylating hydroxyl group of a substance in the presence of a methyl group donor (EC 2.1.1.68 etc.). This activity can also be referred to as an “OMT activity”. A gene encoding OMT can also be referred to as an “OMT gene”. OMT can have a required substrate specificity depending on the specific biosynthesis pathway via which an objective substance is produced in the method as described herein. For example, when an objective substance is produced via the conversion of protocatechuic acid into vanillic acid, OMT that is specific for at least protocatechuic acid can be used. Also, for example, when an objective substance is produced via the conversion of protocatechualdehyde into vanillin, OMT that is specific for at least protocatechualdehyde can be used. That is, specifically, the term “O-methyltransferase (OMT)” can refer to a protein that has the activity of catalyzing the reaction of methylating protocatechuic acid and/or protocatechualdehyde in the presence of a methyl group donor to generate vanillic acid and/or vanillin, that is, methylation of hydroxyl group at the meta-position. OMT may be specific for both protocatechuic acid and protocatechualdehyde as the substrate, but is not necessarily limited thereto. Examples of the methyl group donor can include S-adenosylmethionine (SAM). Examples of an OMT can include OMTs native to various organisms, such as OMT native to Homo sapiens (Hs) (GenBank Accession No. NP_000745 and NP_009294), OMT native to Arabidopsis thaliana (GenBank Accession Nos. NP_200227 and NP_009294), OMT native to Fragaria×ananassa (GenBank Accession No. AAF28353), and other various OMTs native to mammals, plants, and microorganisms exemplified in WO2013/022881A1. Four kinds of transcript variants and two kinds of OMT isoforms are known for the OMT gene native to Homo sapiens. The nucleotide sequences of these four transcript variants (transcript variants 1-4, GenBank Accession No. NM_000754.3, NM_001135161.1, NM_001135162.1, and NM_007310.2) are shown as SEQ ID NOS: 11 to 14, the amino acid sequence of the longer OMT isoform (MB-COMT, GenBank Accession No. NP_000745.1) is shown as SEQ ID NO: 15, and the amino acid sequence of the shorter OMT isoform (S-COMT, GenBank Accession No. NP_009294.1) is shown as SEQ ID NO: 16. SEQ ID NO: 16 corresponds to SEQ ID NO: 15 of which the N-terminal 50 amino acid residues are truncated. Examples of an OMT further can include OMTs native to Bacteroidetes bacteria, that is, bacteria belonging to the phylum Bacteroidetes. Examples of the Bacteroidetes bacteria can include bacteria belonging to the genus Niastella, Terrimonas, Chitinophaga, or the like (International Journal of Systematic and Evolutionary Microbiology (2007), 57, 1828-1833). Examples of the Niastella bacteria can include Niastella koreensis. The nucleotide sequence of the OMT gene native to Niastella koreensis is shown as SEQ ID NO: 130, and the amino acid sequence of OMT encoded by this gene is shown as SEQ ID NO: 131.

OMT may also catalyze the reaction of methylating protocatechuic acid and/or protocatechualdehyde to generate isovanillic acid and/or isovanillin, that is, methylation of hydroxyl group at the para-position, as a side reaction. OMT may selectively catalyze the methylation of a hydroxyl group at the meta-position. The expression “selectively catalyzing the methylation of hydroxyl group at the meta-position” can mean that OMT selectively generates vanillic acid from protocatechuic acid and/or that OMT selectively generates vanillin from protocatechualdehyde. The expression “selectively generating vanillic acid from protocatechuic acid” can mean that OMT generates vanillic acid in an amount of, for example, 3 times or more, 5 times or more, 10 times or more, 15 times or more, 20 times or more, 25 times or more, or 30 times or more of that of isovanillic acid in terms of molar ratio, when OMT is allowed to act on protocatechuic acid. The expression “selectively generating vanillic acid from protocatechuic acid” can also mean that OMT generates vanillic acid in an amount of, for example, 60% or more, 65% or more, 70% or more, 75% or more, 80% or more, 85% or more, 90% or more, or 95% or more, with respect to the total amount of vanillic acid and isovanillic acid in terms of molar ratio, when OMT is allowed to act on protocatechuic acid. This ratio, that is, the ratio of the amount of vanillic acid with respect to the total amount of vanillic acid and isovanillic acid, can also be referred to as “VA/(VA+iVA) ratio”. Also, the phrase “selectively generating vanillin from protocatechualdehyde” can mean that OMT generates vanillin in an amount of, for example, 3 times or more, 5 times or more, 10 times or more, 15 times or more, 20 times or more, 25 times or more, or 30 times or more of that of isovanillin in terms of molar ratio, when OMT is allowed to act on protocatechualdehyde. The expression “selectively generating vanillin from protocatechualdehyde” can also mean that OMT generates vanillin in an amount of, for example, 60% or more, 65% or more, 70% or more, 75% or more, 80% or more, 85% or more, 90% or more, or 95% or more, with respect to the total amount of vanillin and isovanillin in terms of molar ratio, when OMT is allowed to act on protocatechualdehyde. This ratio, that is, the ratio of the amount of vanillin with respect to the total amount of vanillin and isovanillin, can also be referred to as “Vn/(Vn+iVn) ratio”. Examples of OMT that selectively catalyzes the methylation of hydroxyl group at the meta-position can include OMT having a “specific mutation”, which is described herein.

OMT having the “specific mutation” can also be referred to as a “mutant OMT”. A gene encoding a mutant OMT can also be referred to as a “mutant OMT gene”.

OMT not having the “specific mutation” can also be referred to as a “wild-type OMT”. A gene encoding a wild-type OMT can also be referred to as a “wild-type OMT gene”. The term “wild-type” referred to herein is used for convenience to distinguish the “wild-type” OMT from the “mutant” OMT, and the “wild-type” OMT is not limited to those obtained as natural substances, and can include any OMT not having the “specific mutation”. Examples of the wild-type OMT can include, for example, OMTs exemplified above. In addition, all conservative variants of OMTs exemplified above should be included in wild-type OMTs, provided that such conservative variants do not have the “specific mutation”.

Examples of the “specific mutation” can include the mutations present in the mutant OMTs described in WO2013/022881A1. That is, examples of the “specific mutation” can include a mutation that the leucine residue at position 198 of the wild-type OMT (L198) is replaced with an amino acid residue having a hydrophobic index (hydropathy index) lower than that of leucine residue, and a mutation that the glutamate residue at position 199 of the wild-type OMT (E199) is replaced with an amino acid residue having either a neutral or positive side-chain charge at pH 7.4. The mutant OMT may have either one or both of these mutations.

Examples of the “amino acid residue having a hydrophobic index (hydropathy index) lower than that of leucine residue” can include Ala, Arg, Asn, Asp, Cys, Glu, Gln, Gly, His, Lys, Met, Phe, Pro, Ser, Thr, Trp, and Tyr. As the “amino acid residue showing a hydrophobic index (hydropathy index) lower than that of leucine residue”, especially, an amino acid residue selected from Ala, Arg, Asn, Asp, Glu, Gln, Gly, His, Lys, Met, Pro, Ser, Thr, Trp, and Tyr is a particular example, and Tyr is a more particular example.

The “amino acid residue having either a neutral or positive side-chain charge at pH 7.4” can include Ala, Arg, Asn, Cys, Gln, Gly, His, Ile, Leu, Lys, Met, Phe, Pro, Ser, Thr, Trp, Tyr, and Val. As the “amino acid residue having either a neutral or positive side-chain charge at pH 7.4”, Ala or Gln is a particular example.

The terms “L198” and “E199” in an arbitrary wild-type OMT can refer to “an amino acid residue corresponding to the leucine residue at position 198 of the amino acid sequence shown as SEQ ID NO: 16” and “an amino acid residue corresponding to the glutamate residue at position 199 of the amino acid sequence shown as SEQ ID NO: 16”, respectively. The positions of these amino acid residues represent relative positions, and their absolute positions may shift due to deletion, insertion, addition, and so forth of amino acid residue(s). For example, if one amino acid residue is deleted or inserted at a position on the N-terminus side of position X in the amino acid sequence shown as SEQ ID NO: 16, the amino acid residue originally at position X is relocated at position X-1 or X+1, however, it is still regarded as the “amino acid residue corresponding to the amino acid residue at position X of the amino acid sequence shown as SEQ ID NO: 16”. Furthermore, although “L198” and “E199” are typically leucine residue and glutamate residue, respectively, they may not be leucine residue and glutamate residue, respectively. That is, when “L198” and “E199” are not leucine residue and glutamate residue, respectively, the “specific mutation” can include a mutation that those amino acid residues each are replaced with any of the aforementioned amino acid residues.

In the amino acid sequence of an arbitrary OMT, which amino acid residue is the amino acid residue corresponding to “L198” or “E199” can be determined by aligning the amino acid sequence of the arbitrary OMT and the amino acid sequence of SEQ ID NO: 16. The alignment can be performed by, for example, using known gene analysis software. Specific examples of such software can include DNASIS produced by Hitachi Solutions, GENETYX produced by Genetyx, and so forth (Elizabeth C. Tyler et al., Computers and Biomedical Research, 24 (1) 72-96, 1991; Barton G J et al., Journal of Molecular Biology, 198 (2), 327-37, 1987).

Examples of the “specific mutation” further can include mutations at the following amino acid residues: D21, L31, M36, S42, L67, Y90, and P144. The “specific mutation” can be a mutation at one amino acid residue, or can be a combination of mutations at two or more amino acid residues. That is, the “specific mutation” may include, for example, mutations at one or more of the following amino acid residues: D21, L31, M36, S42, L67, Y90, and P144.

In the aforementioned notation for defining amino acid residues, the numbers represent the positions in the amino acid sequence shown as SEQ ID NO: 131, and the letters at the left side of the numbers represent the amino acid residues at the respective positions in the amino acid sequence shown as SEQ ID NO: 131, that is, the amino acid residues before modification at the respective positions. That is, for example, “D21” represents D (Asp) residue at position 21 in the amino acid sequence shown as SEQ ID NO: 131. These amino acid residues in an arbitrary wild-type OMT each can refer to “an amino acid residue corresponding to the indicated amino acid residue in the amino acid sequence shown as SEQ ID NO: 131”. That is, for example, “D21” in an arbitrary wild-type OMT represents an amino acid residue corresponding to D (Asp) residue at position 21 in the amino acid sequence shown as SEQ ID NO: 131.

In each of the aforementioned mutations, the amino acid residue after modification may be any amino acid residue other than the amino acid residue before modification. Examples of the amino acid residue after modification can include K (Lys), R (Arg), H (His), A (Ala), V (Val), L (Leu), I (Ile), G (Gly), S (Ser), T (Thr), P (Pro), F (Phe), W (Trp), Y (Tyr), C (Cys), M (Met), D (Asp), E (Glu), N (Asn), and Q (Gln), provided that the amino acid residues after modification is other than the amino acid residue before modification. As the amino acid residues after modification, there may be selected those effective for production of an objective substance, such as those resulting in an increase in the VA/(VA+iVA) ratio and/or Vn/(Vn+iVn) ratio of OMT.

Specific examples of the “specific mutation” can include the following mutations: D21Y, L31H, M36(K, V), S42C, L67F, Y90(A, C, G, S), and P144(E, G, S, V, Y). That is, the mutations at amino acid residues D21, L31, M36, S42, L67, Y90, and P144 may be, for example, the mutations D21Y, L31H, M36(K, V), S42C, L67F, Y90(A, C, G, S), and P144(E, G, S, V, Y), respectively. The “specific mutation” can include, for example, one or more of the following mutations: D21Y, L31H, M36(K, V), S42C, L67F, Y90(A, C, G, S), and P144(E, G, S, V, Y).

In the aforementioned notation for defining mutations, the numbers and the letters at the left side of the numbers represent the same as described above. In the aforementioned notation for defining mutations, the letters at the right side of the numbers represent the amino acid residues after modification at the respective positions. That is, for example, “D21Y” represents a mutation for replacing D (Asp) residue at position 21 in the amino acid sequence shown as SEQ ID NO: 131 with Y (Tyr) residue. Also, for example, M36(K, V) represents a mutation for replacing M (Met) residue at position 36 in the amino acid sequence shown as SEQ ID NO: 131 with K (Lys) or V (Val) residue. These mutations in an arbitrary wild-type OMT each can refer to “a mutation corresponding to the indicated mutation in the amino acid sequence shown as SEQ ID NO: 131”. A “mutation corresponding to a mutation at the amino acid residue at position X in the amino acid sequence shown in SEQ ID NO: 131” should be read as a mutation at an amino acid residue corresponding to the amino acid residue at position X in the amino acid sequence shown in SEQ ID NO: 131″. That is, for example, “D21Y” in an arbitrary wild-type OMT represents a mutation for replacing an amino acid residue corresponding to D (Asp) residue at position 21 in the amino acid sequence shown as SEQ ID NO: 131 with Y (Tyr) residue.

Combinations of mutations are not particularly limited. Specific examples of combinations of mutations can include D21Y/M36K/L67F, D21Y/M36K/L67F/Y90A, L31H/M36K/L67F/P144V, L31H/L67F/Y90A, M36K/S42C/L67F, M36K/L67F, M36K/L67F/Y90A, M36K/L67F/Y90A/P144E, M36K/L67F/Y90C, M36K/L67F/Y90C/P144V, M36K/L67F/Y90G, M36K/L67F/Y90S/P144G, M36K/L67F/P144S, M36K/L67F/P144Y, M36K/Y90A/P144V, M36K/P144E, and M36V/L67F/P144S. That is, the “specific mutation” may include, for example, any of these combinations.

In the aforementioned notation for defining combinations, the numbers and the letters at the left and right sides of the numbers represent the same as described above. In the aforementioned notation for defining combinations, two or more mutations noted together and inserted with “I” represent a double or more multiple mutation. That is, for example, “M36K/P144E” represents a double mutation of M36K and P144E.

The descriptions regarding the mutations at “L198” or “E199”, such as those for defining the absolute positions thereof, can be applied mutatis mutandis to other “specific mutations” such as the mutations at amino acid residues corresponding to D21, L31, M36, S42, L67, Y90, and P144, provided that the amino acid sequence shown in SEQ ID NO: 131 is used as the reference sequence of the wild-type OMT for the other “specific mutations”.

A mutant OMT gene can be obtained by, for example, modifying a wild-type OMT gene so that OMT encoded thereby has the “specific mutation”. The wild-type OMT gene to be modified can be obtained by, for example, cloning from an organism having the wild-type OMT gene, or chemical synthesis. Alternatively, a mutant OMT gene can also be obtained without using a wild-type OMT gene. For example, a mutant OMT gene may be directly obtained by, for example, cloning from an organism having the mutant OMT gene, or chemical synthesis. The obtained mutant OMT gene may be used as it is, or may be further modified before use. The wild-type OMT gene to be modified or the mutant OMT gene may or may not be derived from the host, such as a microorganism from which the microorganism as described herein is derived.

Genes can be modified by using a known method. For example, an objective mutation can be introduced into a target site of DNA by the site-specific mutagenesis method. Examples of the site-specific mutagenesis method can include a method using PCR (Higuchi, R., 61, in PCR Technology, Erlich, H. A. Eds., Stockton Press (1989); Carter P., Meth. In Enzymol., 154, 382 (1987)), and a method of using a phage (Kramer, W. and Frits, H. J., Meth. in Enzymol., 154, 350 (1987); Kunkel, T. A. et al., Meth. in Enzymol., 154, 367 (1987)).

The OMT activity can be measured by, for example, incubating the enzyme with a substrate, such as protocatechuic acid or protocatechualdehyde, in the presence of SAM, and measuring the enzyme- and substrate-dependent generation of the corresponding product, such as vanillic acid or vanillin (WO2013/022881A1). Furthermore, by measuring the generation of the corresponding by-product, such as isovanillic acid or isovanillin, under the same conditions, and comparing the generation of the by-product with the generation of the product, it can be determined whether OMT selectively generates the product.

The term “aromatic aldehyde oxidoreductase (aromatic carboxylic acid reductase; ACAR)” can refer to a protein that has an activity of catalyzing the reaction of reducing vanillic acid and/or protocatechuic acid in the presence of an electron donor and ATP to generate vanillin and/or protocatechualdehyde (EC 1.2.99.6 etc.). This activity can also be referred to as an “ACAR activity”. A gene encoding an ACAR can also be referred to as an “ACAR gene”. ACAR may generally use both vanillic acid and protocatechuic acid as the substrate, but is not necessarily limited thereto. That is, ACAR can have a required substrate specificity depending on the specific biosynthesis pathway via which an objective substance is produced in the method as described herein. For example, when an objective substance is produced via the conversion of vanillic acid into vanillin, ACAR that is specific for at least vanillic acid can be used. Also, for example, when an objective substance is produced via the conversion of protocatechuic acid into protocatechualdehyde, ACAR that is specific for at least protocatechuic acid can be used. Examples of the electron donor can include NADH and NADPH. Examples of an ACAR can include ACARs native to various organisms such as Nocardia sp. strain NRRL 5646, Actinomyces sp., Clostridium thermoaceticum, Aspergillus niger, Corynespora melonis, Coriolus sp., and Neurospora sp. (J. Biol. Chem., 2007, Vol. 282, No. 1, pp. 478-485). The Nocardia sp. strain NRRL 5646 has been classified into Nocardia iowensis. Examples of an ACAR further can include ACARs native to other Nocardia bacteria such as Nocardia brasiliensis and Nocardia vulneris. The nucleotide sequence of the ACAR gene native to the Nocardia brasiliensis ATCC 700358 strain is shown as SEQ ID NO: 17, and the amino acid sequence of ACAR encoded by this gene is shown as SEQ ID NO: 18. The nucleotide sequence of an example of variant ACAR gene native to the Nocardia brasiliensis ATCC 700358 strain is shown as SEQ ID NO: 19, and the amino acid sequence of ACAR encoded by this gene is shown as SEQ ID NO: 20.

The ACAR activity can be measured by, for example, incubating the enzyme with a substrate, such as vanillic acid or protocatechuic acid, in the presence of ATP and NADPH, and measuring the enzyme- and substrate-dependent oxidation of NADPH (modification of the method described in J. Biol. Chem., 2007, Vol. 282, No. 1, pp. 478-485).

ACAR can be made into an active enzyme by phosphopantetheinylation (J. Biol. Chem., 2007, Vol. 282, No. 1, pp. 478-485). Therefore, ACAR activity can also be increased by increasing the activity of an enzyme that catalyzes phosphopantetheinylation of a protein, which can also be referred to as a “phosphopantetheinylation enzyme”. That is, examples of the methods for imparting or enhancing an objective substance-producing ability can include a method of increasing the activity of a phosphopantetheinylation enzyme. That is, the microorganism can be modified so that the activity of a phosphopantetheinylation enzyme is increased. Examples of the phosphopantetheinylation enzyme can include phosphopantetheinyl transferase (PPT).

The term “phosphopantetheinyl transferase (PPT)” can refer to a protein that has an activity of catalyzing the reaction of phosphopantetheinylating ACAR in the presence of a phosphopantetheinyl group donor. This activity can also be referred to as a “PPT activity”. A gene encoding a PPT can also be referred to as a “PPT gene”. Examples of the phosphopantetheinyl group donor can include coenzyme A (CoA). Examples of a PPT can include an EntD protein, which is encoded by an entD gene. Examples of a PPT such as the EntD protein can include those native to various organisms. Specific examples of a PPT can include the EntD protein native to E. coli. The nucleotide sequence of the entD gene native to the E. coli K-12 MG1655 strain is shown as SEQ ID NO: 21, and the amino acid sequence of the EntD protein encoded by this gene is shown as SEQ ID NO: 22. Specific examples of a PPT can also include PPT native to Nocardia brasiliensis, PPT native to Nocardia farcinica IFM10152 (J. Biol. Chem., 2007, Vol. 282, No. 1, pp. 478-485), and PPT native to Corynebacterium glutamicum (App. Env. Microbiol. 2009, Vol. 75, No. 9, pp. 2765-2774). The nucleotide sequence of the PPT gene native to the C. glutamicum ATCC 13032 strain is shown as SEQ ID NO: 23, and the amino acid sequence of PPT encoded by this gene is shown as SEQ ID NO: 24.

The PPT activity can be measured on the basis of, for example, enhancement of the ACAR activity observed when the enzyme is incubated with ACAR in the presence of CoA (J. Biol. Chem., 2007, Vol. 282, No. 1, pp. 478-485).

Melatonin can be produced from L-tryptophan. That is, examples of the objective substance biosynthesis enzyme can also include, for example, L-tryptophan biosynthesis enzymes and enzymes that catalyze the conversion of L-tryptophan into melatonin. Examples of the L-tryptophan biosynthesis enzymes can include common biosynthesis enzymes of aromatic amino acids, such as 3-deoxy-D-arabinoheptulosonate-7-phosphate synthase (aroF, aroG, aroH), 3-dehydroquinate synthase (aroB), 3-dehydroquinate dehydratase (aroD), shikimate dehydrogenase (aroF), shikimate kinase (aroK, aroL), 5-enolpyruvylshikimate-3-phosphate synthase (aroA), and chorismate synthase (aroC); as well as anthranilate synthase (trpED), and tryptophan synthase (trpAB). Shown in the parentheses after the names of the enzymes are examples of the names of the genes encoding the enzymes (the same shall apply to the same occasions hereafter). L-tryptophan can be converted successively to hydroxytryptophan, serotonin, N-acetylserotonin, and melatonin by the action of tryptophan 5-hydroxylase (EC 1.14.16.4), 5-hydroxytryptophan decarboxylase (EC 4.1.1.28), aralkylamine N-acetyltransferase (AANAT; EC 2.3.1.87), and acetylserotonin O-methyltransferase (EC 2.1.1.4). That is, examples of enzymes that catalyze the conversion of L-tryptophan into melatonin can include these enzymes. Notably, acetylserotonin O-methyltransferase is an example of OMT that catalyzes the reaction of methylating N-acetylserotonin to generate melatonin, using SAM as the methyl donor.

Ergothioneine can be produced from L-histidine. That is, examples of the objective substance biosynthesis enzyme can also include, for example, L-histidine biosynthesis enzymes and enzymes that catalyze the conversion of L-histidine into ergothioneine. Examples of the L-histidine biosynthesis enzymes can include ATP phosphoribosyltransferase (hisG), phosphoribosyl-AMP cyclohydrolase (hisI), phosphoribosyl-ATP pyrophosphohydrolase (hisI), phosphoribosylformimino-5-aminoimidazole carboxamide ribotide isomerase (hisA), amidotransferase (hisH), histidinol phosphate aminotransferase (hisC), histidinol phosphatase (hisB), and histidinol dehydrogenase (hisD). L-histidine can be converted successively to hercynine, hercynyl-gamma-L-glutamyl-L-cysteine sulfoxide, hercynyl-L-cysteine sulfoxide, and ergothioneine by the action of the EgtB, EgtC, EgtD, and EgtE proteins, which are encoded by the egtB, egtC, egtD, and egtE genes, respectively. Hercynine can also be converted to hercynyl-L-cysteine sulfoxide by the action of the Egt1 protein, which is encoded by the egt1 gene. That is, examples of the enzymes that catalyze the conversion of L-histidine into ergothioneine can include these enzymes. Notably, EgtD is an S-adenosyl-1-methionine (SAM)-dependent histidine N,N,N-methyltransferase that catalyzes the reaction of methylating histidine to generate hercynine, using SAM as the methyl donor.

Guaiacol can be produced from vanillic acid. Hence, the aforementioned descriptions concerning objective substance biosynthesis enzymes for vanillic acid can be applied mutatis mutandis to objective substance biosynthesis enzymes for guaiacol. Vanillic acid can be converted to guaiacol by the action of vanillic acid decarboxylase (VDC). That is, examples of the objective substance biosynthesis enzyme can also include VDC.

Ferulic acid, 4-vinylguaiacol, and 4-ethylguaiacol can be produced from L-phenylalanine or L-tyrosine. That is, examples of the objective substance biosynthesis enzyme can also include, for example, L-phenylalanine biosynthesis enzymes, L-tyrosine biosynthesis enzymes, and enzymes that catalyze the conversion of L-phenylalanine or L-tyrosine into ferulic acid, 4-vinylguaiacol, or 4-ethylguaiacol. Examples of the L-phenylalanine biosynthesis enzymes can include the common biosynthesis enzymes of aromatic amino acids exemplified above, as well as chorismate mutase (pheA), prephenate dehydratase (pheA), and tyrosine amino transferase (tyrB). Chorismate mutase and prephenate dehydratase may be encoded by the pheA gene as a bifunctional enzyme. Examples of the L-tyrosine biosynthesis enzymes can include the common biosynthesis enzymes of aromatic amino acids exemplified above, as well as chorismate mutase (tyrA), prephenate dehydrogenase (tyrA), and tyrosine amino transferase (tyrB). Chorismate mutase and prephenate dehydrogenase may be encoded by the tyrA gene as a bifunctional enzyme. L-phenylalanine can be converted to cinnamic acid by the action of phenylalanine ammonia lyase (PAL; EC 4.3.1.24), and then to p-coumaric acid by the action of cinnamic acid 4-hydroxylase (C4H; EC 1.14.13.11). Also, L-tyrosine can be converted to p-coumaric acid by the action of tyrosine ammonia lyase (TAL; EC 4.3.1.23). p-Coumaric acid can be converted successively to caffeic acid, ferulic acid, 4-vinylguaiacol, and 4-ethylguaiacol by the action of hydroxycinnamic acid 3-hydroxylase (C3H), O-methyltransferase (OMT), ferulic acid decarboxylase (FDC), and vinylphenol reductase (VPR), respectively. That is, examples of enzymes that catalyze the conversion of L-phenylalanine or L-tyrosine into ferulic acid, 4-vinylguaiacol, or 4-ethylguaiacol can include these enzymes. For producing ferulic acid, 4-vinylguaiacol, or 4-ethylguaiacol, OMT that uses at least caffeic acid can be used.

Polyamines can be produced from L-arginine or L-ornithine. That is, examples of the objective substance biosynthesis enzyme can also include, for example, L-arginine biosynthesis enzymes, L-ornithine biosynthesis enzymes, and enzymes that catalyze the conversion of L-arginine or L-ornithine into a polyamine. Examples of the L-ornithine biosynthesis enzymes can include N-acetylglutamate synthase (argA), N-acetylglutamate kinase (argB), N-acetylglutamyl phosphate reductase (argC), acetylornithine transaminase (argD), and acetylornithine deacetylase (argE). Examples of the L-arginine biosynthesis enzymes can include the L-ornithine biosynthesis enzymes exemplified above, as well as carbamoyl phosphate synthetase (carAB), ornithine carbamoyl transferase (argF, argl), argininosuccinate synthetase (argG), argininosuccinate lyase (argH). L-arginine can be converted to agmatine by the action of arginine decarboxylase (speA; EC 4.1.1.19), and then to putrescine by the action of agmatine ureohydrolase (speB; EC 3.5.3.11). Also, L-ornithine can be converted to putrescine by the action of ornithine decarboxylase (speC; EC 4.1.1.17). Putrescine can be converted to spermidine by the action of spermidine synthase (speE; EC 2.5.1.16), and then to spermine by the action of spermine synthase (EC 2.5.1.22). Agmatine can also be converted to aminopropylagmatine by the action of agmatine/triamine aminopropyl transferase, and then to spermidine by the action of aminopropylagmatine ureohydrolase. That is, examples of the enzymes that catalyze the conversion of L-arginine or L-ornithine into a polyamine can include these enzymes. Notably, spermidine synthase, spermine synthase, and agmatine/triamine aminopropyl transferase each catalyze the reaction of transferring a propylamine group from decarboxylated S-adenosyl methionine (dcSAM), which can be generated from SAM by decarboxylation, into the corresponding substrate.

Creatine can be produced from L-arginine and glycine. That is, examples of the objective substance biosynthesis enzyme can also include, for example, L-arginine biosynthesis enzymes, glycine biosynthesis enzymes, and enzymes that catalyze the conversion of L-arginine and glycine into creatine. L-arginine and glycine can be combined to generate guanidinoacetate and ornithine by the action of arginine:glycine amidinotransferase (AGAT, EC 2.1.4.1); and guanidinoacetate can be methylated to generate creatine by the action of guanidinoacetate N-methyltransferase (GAMT, EC 2.1.1.2), using SAM as the methyl donor. That is, examples of the enzymes that catalyze the conversion of L-arginine and glycine into creatine can include these enzymes.

Mugineic acid can be produced from SAM. That is, examples of the objective substance biosynthesis enzyme can also include, for example, enzymes that catalyze the conversion of SAM into mugineic acid. One molecule of nicotianamine can be synthesized from three molecules of SAM by the action of nicotianamine synthase (EC 2.5.1.43). Nicotianamine can be converted successively to 3″-deamino-3″-oxonicotianamine, 2′-deoxymugineic-acid, and mugineic-acid by the action of nicotianamine aminotransferase (EC 2.6.1.80), 3″-deamino-3″-oxonicotianamine reductase (EC 1.1.1.285), and 2′-deoxymugineic-acid 2′-dioxygenase (EC 1.14.11.24), respectively. That is, examples of the enzymes that catalyze the conversion of SAM into mugineic acid can include these enzymes.

L-Methionine can be produced from L-cysteine. That is, examples of the objective substance biosynthesis enzyme can also include, for example, L-cysteine biosynthesis enzymes and enzymes that catalyze the conversion of L-cysteine into L-methionine. Examples of the L-cysteine biosynthesis enzymes can include the CysIXHDNYZ proteins, Fpr2 protein, and CysK protein described herein. Examples of the enzymes that catalyze the conversion of L-cysteine into L-methionine can include cystathionine-gamma-synthase and cystathionine-beta-lyase.

Examples of the methods for imparting or enhancing an objective substance-producing ability can also include a method of increasing the activity of an uptake system of a substance other than an objective substance, such as a substance generated as an intermediate during production of an objective substance and a substance used as a precursor of an objective substance. That is, the microorganism may have been modified so that the activity of such an uptake system is increased. The term “uptake system of a substance” can refer to a protein having a function of incorporating the substance from the outside of a cell into the cell. This activity can also be referred to as an “uptake activity of a substance”. A gene encoding such an uptake system can also be referred to as an “uptake system gene”. Examples of such an uptake system can include a vanillic acid uptake system and a protocatechuic acid uptake system. Examples of the vanillic acid uptake system can include a VanK protein, which is encoded by a vanK gene (M. T. Chaudhry, et al., Microbiology, 2007, 153:857-865). The nucleotide sequence of the vanK gene (NCgl2302) native to the C. glutamicum ATCC 13869 strain is shown as SEQ ID NO: 25, and the amino acid sequence of the VanK protein encoded by this gene is shown as SEQ ID NO: 26. Examples of the protocatechuic acid uptake system gene can include a PcaK protein, which is encoded by a pcaK gene (M. T. Chaudhry, et al., Microbiology, 2007, 153:857-865). The nucleotide sequence of the pcaK gene (NCgl1031) native to the C. glutamicum ATCC 13869 strain is shown as SEQ ID NO: 27, and the amino acid sequence of the PcaK protein encoded by this gene is shown as SEQ ID NO: 28.

The uptake activity of a substance can be measured according to, for example, a known method (M. T. Chaudhry, et al., Microbiology, 2007. 153:857-865).

Examples of the methods for imparting or enhancing an objective substance-producing ability further can include a method of reducing the activity of an enzyme that is involved in the by-production of a substance other than an objective substance. Such a substance other than an objective substance can also be referred to as a “byproduct”. Such an enzyme can also be referred to as a “byproduct generation enzyme”. Examples of the byproduct generation enzyme can include, for example, enzymes that are involved in the utilization of an objective substance, and enzymes that catalyze a reaction branching away from the biosynthetic pathway of an objective substance to generate a substance other than the objective substance. The method for reducing the activity of a protein, such as an enzyme etc., will be described herein. The activity of a protein, such as an enzyme etc., can be reduced by, for example, disrupting a gene that encodes the protein. For example, it has been reported that, in coryneform bacteria, vanillin is metabolized in the order of vanillin→vanillic acid→protocatechuic acid, and utilized (Current Microbiology, 2005, Vol. 51, pp. 59-65). That is, specific examples of the byproduct generation enzyme can include an enzyme that catalyzes the conversion of vanillin into protocatechuic acid and enzymes that catalyze further metabolization of protocatechuic acid. Examples of such enzymes can include vanillate demethylase, protocatechuate 3,4-dioxygenase, and various enzymes that further decompose the reaction product of protocatechuate 3,4-dioxygenase to succinyl-CoA and acetyl-CoA (Appl. Microbiol. Biotechnol., 2012, Vol. 95, p 77-89). In addition, vanillin can be converted into vanillyl alcohol by the action of alcohol dehydrogenase (Kunjapur A M. et al., J. Am. Chem. Soc., 2014, Vol. 136, p 11644-11654.; Hansen E H. et al., App. Env. Microbiol., 2009, Vol. 75, p 2765-2774.). That is, specific examples of the byproduct generation enzyme can also include alcohol dehydrogenase (ADH). In addition, 3-dehydroshikimic acid, which is an intermediate of the biosynthetic pathway of vanillic acid and vanillin, can also be converted into shikimic acid by the action of shikimate dehydrogenase. That is, specific examples of the byproduct generation enzyme can also include shikimate dehydrogenase.

The term “vanillate demethylase” can refer to a protein having an activity for catalyzing the reaction of demethylating vanillic acid to generate protocatechuic acid. This activity can also be referred to as a “vanillate demethylase activity”. A gene encoding vanillate demethylase can also be referred to as a “vanillate demethylase gene”. Examples of a vanillate demethylase can include VanAB proteins, which are encoded by vanAB genes (Current Microbiology, 2005, Vol. 51, pp. 59-65). The vanA gene and vanB gene encode the subunit A and subunit B of vanillate demethylase, respectively. To reduce the vanillate demethylase activity, both the vanAB genes may be disrupted or the like, or only one of the two may be disrupted or the like. The nucleotide sequences of the vanAB genes native to the C. glutamicum ATCC 13869 strain are shown as SEQ ID NOS: 29 and 31, and the amino acid sequences of the VanAB proteins encoded by these genes are shown as SEQ ID NOS: 30 and 32, respectively. The vanAB genes typically constitute the vanABK operon together with the vanK gene. Therefore, in order to reduce the vanillate demethylase activity, the vanABK operon may be totally disrupted or the like, for example, deleted. In such a case, the vanK gene may be introduced to a host again. For example, when vanillic acid present outside cells is used, and the vanABK operon is totally disrupted or the like, for example, deleted, it is preferable to introduce the vanK gene anew.

The vanillate demethylase activity can be measured by, for example, incubating the enzyme with a substrate such as vanillic acid, and measuring the enzyme- and substrate-dependent generation of protocatechuic acid (J Bacteriol, 2001, Vol. 183, p 32′76-3281).

The term “protocatechuate 3,4-dioxygenase” can refer to a protein having an activity for catalyzing the reaction of oxidizing protocatechuic acid to generate beta-Carboxy-cis,cis-muconic acid. This activity can also be referred to as a “protocatechuate 3,4-dioxygenase activity”. A gene encoding protocatechuate 3,4-dioxygenase can also be referred to as a “protocatechuate 3,4-dioxygenase gene”. Examples of a protocatechuate 3,4-dioxygenase can include PcaGH proteins, which are encoded by pcaGH genes (Appl. Microbiol. Biotechnol., 2012, Vol. 95, p 77-89). The pcaG gene and pcaH gene encode the alpha subunit and beta subunit of protocatechuate 3,4-dioxygenase, respectively. To reduce the protocatechuate 3,4-dioxygenase activity, both the pcaGH genes may be disrupted or the like, or only one of the two may be disrupted or the like. The nucleotide sequences of the pcaGH genes native to the C. glutamicum ATCC 13032 strain are shown as SEQ ID NOS: 33 and 35, and the amino acid sequences of the PcaGH proteins encoded by these genes are shown as SEQ ID NOS: 34 and 36, respectively.

The protocatechuate 3,4-dioxygenase activity can be measured by, for example, incubating the enzyme with a substrate, such as protocatechuic acid, and measuring the enzyme- and substrate-dependent oxygen consumption (Meth. Enz., 1970, Vol. 17A, p 526-529).

The term “alcohol dehydrogenase (ADH)” can refer to a protein that has an activity for catalyzing the reaction of reducing an aldehyde in the presence of an electron donor to generate an alcohol (EC 1.1.1.1, EC 1.1.1.2, EC 1.1.1.71, etc.). This activity can also be referred to as an “ADH activity”. A gene encoding an ADH can also be referred to as an “ADH gene”. Examples of the electron donor can include NADH and NADPH.

As ADH, one having an activity for catalyzing the reaction of reducing vanillin in the presence of an electron donor to generate vanillyl alcohol is a particular example. This activity can also be especially referred to as a “vanillyl alcohol dehydrogenase activity”. Furthermore, ADH having the vanillyl alcohol dehydrogenase activity can also be especially referred to as a “vanillyl alcohol dehydrogenase”.

Examples of an ADH can include a YqhD protein, NCgl0324 protein, NCgl0313 protein, NCgl2709 protein, NCgl0219 protein, and NCgl2382 protein, which are encoded by a yqhD gene, NCgl0324 gene, NCgl0313 gene, NCgl2709 gene, NCgl0219 gene, and NCgl2382 gene, respectively. The yqhD gene and the NCgl0324 gene encode vanillyl alcohol dehydrogenase. The yqhD gene can be found in, for example, bacteria belonging to the family Enterobacteriaceae such as E. coli. The NCgl0324 gene, NCgl0313 gene, NCgl2709 gene, NCgl0219 gene, and NCgl2382 gene can be found in, for example, coryneform bacteria such as C. glutamicum. The nucleotide sequence of the yqhD gene native to the E. coli K-12 MG1655 strain is shown as SEQ ID NO: 37, and the amino acid sequence of the YqhD protein encoded by this gene is shown as SEQ ID NO: 38. The nucleotide sequences of the NCgl0324 gene, NCgl0313 gene, and NCgl2709 gene native to the C. glutamicum ATCC 13869 strain are shown as SEQ ID NOS: 39, 41, and 43, respectively, and the amino acid sequences of the proteins encoded by these genes are shown as SEQ ID NOS: 40, 42, and 44, respectively. The nucleotide sequences of the NCgl0219 gene and NCgl2382 gene native to the C. glutamicum ATCC 13032 strain are shown as SEQ ID NOS: 45 and 47, respectively, and the amino acid sequences of the proteins encoded by these genes are shown as SEQ ID NOS: 46 and 48, respectively. The activity of one kind of ADH may be reduced, or the activities of two or more kinds of ADHs may be reduced. For example, the activity or activities of one or more of the NCgl0324 protein, NCgl2709 protein, and NCgl0313 protein may be reduced. Particularly, at least the activity of NCgl0324 protein may be reduced.

The ADH activity can be measured by, for example, incubating the enzyme with a substrate, that is, an aldehyde such as vanillin, in the presence of NADPH or NADH, and measuring the enzyme- and substrate-dependent oxidation of NADPH or NADH.

The term “shikimate dehydrogenase” can refer to a protein that has the activity of catalyzing the reaction of reducing 3-dehydroshikimic acid in the presence of an electron donor to generate shikimic acid (EC 1.1.1.25). This activity can also be referred to as a “shikimate dehydrogenase activity”. A gene encoding a shikimate dehydrogenase can also be referred to as a “shikimate dehydrogenase gene”. Examples of the electron donor can include NADH and NADPH. Examples of a shikimate dehydrogenase can include an AroE protein, which is encoded by an aroE gene. The nucleotide sequence of the aroE gene native to the E. coli K-12 MG1655 strain is shown as SEQ ID NO: 49, and the amino acid sequence of the AroE protein encoded by this gene is shown as SEQ ID NO: 50.

The shikimate dehydrogenase activity can be measured by, for example, incubating the enzyme with a substrate, such as 3-dehydroshikimic acid, in the presence of NADPH or NADH, and measuring the enzyme- and substrate-dependent oxidation of NADPH or NADH.

Examples of the methods for imparting or enhancing an objective substance-producing ability further can include a method of increasing the activity of an L-cysteine biosynthesis enzyme.

The term “L-cysteine biosynthesis enzyme” can refer to a protein that is involved in L-cysteine biosynthesis. A gene encoding the L-cysteine biosynthesis enzyme can also be referred to as an “L-cysteine biosynthesis gene”. Examples of the L-cysteine biosynthesis enzyme can include proteins that are involved in sulfur utilization. Examples of the proteins that are involved in sulfur utilization can include CysIXHDNYZ proteins and an Fpr2 protein, which are encoded by cysIXHDNYZ genes and an fpr2 gene, respectively. The CysIXHDNYZ proteins are involved specifically in the reduction of inorganic sulfur compounds such as sulfate and sulfite. Fpr2 protein may be involved specifically in electron transport for the reduction of sulfite. Examples of the L-cysteine biosynthesis enzyme can also include O-acetylserine (thiol)-lyase. Examples of O-acetylserine (thiol)-lyase can include a CysK protein, which is encoded by a cysK gene. Examples of L-cysteine biosynthesis enzyme can include those native to various organisms such as Enterobacteriaceae bacteria and coryneform bacteria. Specific examples of L-cysteine biosynthesis enzyme can include the CysIXHDNYZ proteins, Fpr2 protein, and CysK protein native to C. glutamicum. The nucleotide sequences of the cysIXHDNYZ genes and fpr2 gene native to the C. glutamicum ATCC 13869 strain are shown as SEQ ID NOS: 88, 90, 92, 94, 96, 98, 100, and 102, respectively, and the amino acid sequences of the proteins encoded by these genes are shown as SEQ ID NOS: 89, 91, 93, 95, 97, 99, 101, and 103, respectively. The activity of one kind of L-cysteine biosynthesis enzyme may be increased, or the activities of two or more kinds of L-cysteine biosynthesis enzymes may be increased. For example, the activities of one or more of the CysIXHDNYZ proteins, Fpr2 protein, and CysK protein may be increased, or the activities of one or more of the CysIXHDNYZ proteins and Fpr2 protein may be increased.

The activity of an L-cysteine biosynthesis enzyme can be increased by, for example, increasing the expression of a gene encoding the L-cysteine biosynthesis enzyme, that is, an L-cysteine biosynthesis gene such as the cysIXHDNYZ genes, fpr2 gene, and cysK gene.

The expression of an L-cysteine biosynthesis gene can be increased by, for example, modifying, such as increasing or reducing, the activity of an expression regulator of the gene. That is, the expression of an L-cysteine biosynthesis gene can be increased by, for example, increasing the activity of a positive expression regulator, such as an activator, of the gene. Also, the expression of an L-cysteine biosynthesis gene can be increased by, for example, reducing the activity of a negative expression regulator, such as a repressor, of the gene. Such a regulator can also be referred to as a “regulator protein”. A gene encoding such a regulator can also be referred to as a “regulator gene”.

Examples of such an activator can include a CysR protein and an SsuR protein, which are encoded by a cysR gene and an ssuR gene, respectively. An increased activity of the CysR protein may result in an increased expression of one or more of the cysIXHDNYZ genes, fpr2 gene, and ssuR gene. Also, an increased activity of the SsuR protein may result in an increased expression of gene(s) involved in utilization of organic sulfur compounds. Examples of such an activator can include those native to various organisms such as Enterobacteriaceae bacteria and coryneform bacteria. Specific examples of such an activator can include the CysR protein and SsuR protein native to C. glutamicum. The nucleotide sequences of the cysR gene (NCgl0120) and ssuR gene native to the C. glutamicum ATCC 13869 strain are shown as SEQ ID NOS: 104 and 106, respectively, and the amino acid sequences of the proteins encoded by these genes are shown as SEQ ID NOS: 105 and 107, respectively. The activity or activities of either one or both of the CysR protein and SsuR protein may be increased. For example, the activity of at least the CysR protein may be increased. The activity of such an activator can be increased by, for example, increasing the expression of a gene encoding the activator.

Examples of such a repressor can include the McbR protein, which is encoded by the mcbR gene. A reduced activity of the McbR protein may result in an increased expression of one or more of the cysR gene and ssuR gene, and thereby may further result in an increased expression of one or more of the cysIXHDNYZ genes and fpr2 gene. The activity of such a repressor can be reduced by, for example, reducing the expression of a gene encoding the repressor or by disrupting a gene encoding the repressor.

That is, specifically, the activity of an L-cysteine biosynthesis enzyme can be increased by, for example, increasing the expression of one or more of the cysIXHDNYZ genes, fpr2 gene, cysR gene, and ssuR gene. Therefore, the phrase “the activity of an L-cysteine biosynthesis enzyme is increased” can mean that, for example, the expression of one or more of the cysIXHDNYZ genes, fpr2 gene, cysR gene, and ssuR gene is increased. For example, the expression of at least the cysR gene may be increased. Also, for example, the expression of all of these genes may be increased. The expression of one or more of the cysIXHDNYZ genes, fpr2 gene, and ssuR gene may be increased by increasing the expression of the cysR gene.

Examples of the methods for imparting or enhancing an objective substance-producing ability further can include a method of reducing the activity of the NCgl2048 protein.

The term “NCgl2048 protein” can refer to a protein encoded by an NCgl2048 gene. Examples of an NCgl2048 protein can include those native to various organisms such as Enterobacteriaceae bacteria and coryneform bacteria. Specific examples of an NCgl2048 protein can include the NCgl2048 protein native to C. glutamicum. The nucleotide sequence of the NCgl2048 gene native to the C. glutamicum ATCC 13869 strain is shown as SEQ ID NO: 119, and the amino acid sequence of the protein encoded by this gene is shown as SEQ ID NO: 120. Incidentally, the original function of the NCgl2048 protein regarding conservative variants described herein can mean the function of the protein having the amino acid sequence shown as SEQ ID NO: 120, or may also mean a property that a reduction in the activity of the protein in a microorganism provides an increased production of an objective substance.

Examples of the methods for imparting or enhancing an objective substance-producing ability further can include a method of reducing the activity of enolase.

The term “enolase” can refer to a protein that has the activity of catalyzing the reaction of dehydrating 2-phospho-D-glyceric acid to generate phosphoenolpyruvic acid (EC 4.2.1.11). This activity can also be referred to as an “enolase activity”. Enolase can also be referred to as “phosphopyruvate hydratase”. A gene encoding an enolase can also be referred to as an “enolase gene”. Examples of an enolase can include an Eno protein, which is encoded by an eno gene. Examples of an enolase such as the Eno protein can include those native to various organisms such as Enterobacteriaceae bacteria and coryneform bacteria. Specific examples of an enolase can include the Eno protein native to C. glutamicum. The nucleotide sequence of the eno gene (NCgl0935) native to the C. glutamicum ATCC 13869 strain is shown as SEQ ID NO: 128, and the amino acid sequence of the Eno protein encoded by this gene is shown as SEQ ID NO: 129.

The enolase activity can be measured by, for example, incubating the enzyme with a substrate, such as 2-phospho-D-glyceric acid, and measuring the enzyme- and substrate-dependent generation of phosphoenolpyruvic acid.

Examples of the methods for imparting or enhancing an objective substance-producing ability further can include a method of reducing the activity of L-serine deaminase.

The term “L-serine deaminase” can refer to a protein that has the activity of catalyzing the reaction of converting L-serine into pyruvic acid and ammonia (EC 4.3.1.17). This activity can also be referred to as an “L-serine deaminase activity”. L-serine deaminase can also be referred to as “L-serine ammonia-lyase”. A gene encoding an L-serine deaminase can also be referred to as a “L-serine deaminase gene”. Examples of an L-serine deaminase can include an SdaA protein, which is encoded by an sdaA gene. Examples of an L-serine deaminase such as the SdaA protein can include those native to various organisms such as Enterobacteriaceae bacteria and coryneform bacteria. Specific examples of an L-serine deaminase can include the SdaA protein native to C. glutamicum. The nucleotide sequence of the sdaA gene (NCgl1583) native to the C. glutamicum ATCC 13869 strain is shown as SEQ ID NO: 146, and the amino acid sequence of the SdaA protein encoded by this gene is shown as SEQ ID NO: 147.

The L-serine deaminase activity can be measured by, for example, incubating the enzyme with a substrate, such as L-serine, and measuring the enzyme- and substrate-dependent generation of pyruvic acid or ammonia.

Examples of the methods for imparting or enhancing an objective substance-producing ability further can include a method of reducing the activity of AICAR formyltransferase/IMP cyclohydrolase or modifying a gene encoding AICAR formyltransferase/IMP cyclohydrolase so as to have the “specific mutation” described herein.

The term “AICAR formyltransferase/IMP cyclohydrolase” can refer to AICAR formyltransferase and/or IMP cyclohydrolase, that is, either one or both of AICAR formyltransferase and IMP cyclohydrolase. The term “AICAR formyltransferase” can refer to a protein that has the activity of catalyzing the reaction of converting 5-amino-1-(5-phospho-D-ribosyl)imidazole-4-carboxamide (AICAR) and 10-formyltetrahydrofolate into 5-formamido-1-(5-phospho-D-ribosyl)imidazole-4-carboxamide (FAICAR) and tetrahydrofolate (EC 2.1.2.3). This activity can also be referred to as an “AICAR formyltransferase activity”. The term “IMP cyclohydrolase” can refer to a protein that has the activity of catalyzing the reaction of dehydrating FAICAR to generate IMP (EC 3.5.4.10). This activity can also be referred to as an “IMP cyclohydrolase activity”. A gene encoding an AICAR formyltransferase/IMP cyclohydrolase can also be referred to as an “AICAR formyltransferase/IMP cyclohydrolase gene”. AICAR formyltransferase and IMP cyclohydrolase may be encoded as a bifunctional enzyme. Hence, the term “AICAR formyltransferase/IMP cyclohydrolase” can specifically refer to a bifunctional AICAR formyltransferase/IMP cyclohydrolase, i.e. a protein having both the AICAR formyltransferase activity and IMP cyclohydrolase activity. Examples of an AICAR formyltransferase/IMP cyclohydrolase can include a PurH protein, which is a bifunctional AICAR formyltransferase/IMP cyclohydrolase encoded by a purH gene. Examples of an AICAR formyltransferase/IMP cyclohydrolase such as the PurH protein can include those native to various organisms such as Enterobacteriaceae bacteria and coryneform bacteria. Specific examples of an AICAR formyltransferase/IMP cyclohydrolase can include the PurH protein native to C. glutamicum. The nucleotide sequence of the purH gene (NCgl0827) native to the C. glutamicum ATCC 13869 strain is shown as SEQ ID NO: 134, and the amino acid sequence of the PurH protein encoded by this gene is shown as SEQ ID NO: 135.

The AICAR formyltransferase/IMP cyclohydrolase activity can be measured by, for example, incubating the enzyme with a substrate, such as AICAR and 10-formyltetrahydrofolate for AICAR formyltransferase; FAICAR for IMP cyclohydrolase, and measuring the enzyme- and substrate-dependent generation of the corresponding product, such as FAICAR or tetrahydrofolate for AICAR formyltransferase; IMP for IMP cyclohydrolase. Generation of tetrahydrofolate can be measured on the basis of absorbance at 298 nm (Rayl E A, et al (1996) JBC 271:2225-33). Furthermore, the AICAR formyltransferase activity and the IMP cyclohydrolase activity can be collectively measured by, for example, incubating the enzyme with the substrate for AICAR formyltransferase, such as AICAR and 10-formyltetrahydrofolate, and measuring the enzyme- and substrate-dependent generation of the product for IMP cyclohydrolase, such as IMP. It is sufficient that AICAR formyltransferase/IMP cyclohydrolase has the AICAR formyltransferase/IMP cyclohydrolase activity that is measured under at least one appropriate condition. In other words, it is sufficient that the microorganism is modified so that the activity of AICAR formyltransferase/IMP cyclohydrolase is reduced when the activity is measured under at least one appropriate condition. Incidentally, it is also sufficient that all the other proteins referred to herein have the respective activities that are each measured under at least one appropriate condition.

Methods for reducing the activity of a protein such as AICAR formyltransferase/IMP cyclohydrolase will be explained herein. The activity of AICAR formyltransferase/IMP cyclohydrolase can be reduced by, for example, attenuating the expression of a gene encoding AICAR formyltransferase/IMP cyclohydrolase, or disrupting a gene encoding AICAR formyltransferase/IMP cyclohydrolase. Furthermore, in an embodiment, the activity of AICAR formyltransferase/IMP cyclohydrolase may also be reduced by, for example, modifying a gene encoding AICAR formyltransferase/IMP cyclohydrolase so as to have the “specific mutation”. Such methods for reducing the activity of AICAR formyltransferase/IMP cyclohydrolase may be used independently or in an arbitrary combination.

The microorganism may be modified so that a gene encoding AICAR formyltransferase/IMP cyclohydrolase has the “specific mutation”.

The “specific mutation” is a mutation that results in improving an objective substance-producing ability of the microorganism. The term “specific mutation” in reference to the AICAR formyltransferase/IMP cyclohydrolase gene can refer to a change in the nucleotide sequence of the AICAR formyltransferase/IMP cyclohydrolase gene. The “specific mutation” can provide a change in the amino acid sequence of the encoded AICAR formyltransferase/IMP cyclohydrolase. Accordingly, the term “specific mutation” may also be used for AICAR formyltransferase/IMP cyclohydrolase as a term referring to a change in the amino acid sequence of AICAR formyltransferase/IMP cyclohydrolase provided by the “specific mutation” in the AICAR formyltransferase/IMP cyclohydrolase gene. That is, the phrase “an AICAR formyltransferase/IMP cyclohydrolase gene has the “specific mutation”” may be read as that AICAR formyltransferase/IMP cyclohydrolase encoded by the gene has the “specific mutation”.

AICAR formyltransferase/IMP cyclohydrolase having the “specific mutation” can also be referred to as a “mutant AICAR formyltransferase/IMP cyclohydrolase”. A gene encoding a mutant AICAR formyltransferase/IMP cyclohydrolase, that is, an AICAR formyltransferase/IMP cyclohydrolase gene having the “specific mutation”, can also be referred to as “mutant AICAR formyltransferase/IMP cyclohydrolase gene”.

AICAR formyltransferase/IMP cyclohydrolase not having the “specific mutation” can also be referred to as a “wild-type AICAR formyltransferase/IMP cyclohydrolase”. A gene encoding a wild-type AICAR formyltransferase/IMP cyclohydrolase, that is, an AICAR formyltransferase/IMP cyclohydrolase gene not having the “specific mutation”, can also be referred to as a “wild-type AICAR formyltransferase/IMP cyclohydrolase gene”. Examples of the wild-type AICAR formyltransferase/IMP cyclohydrolase gene or wild-type AICAR formyltransferase/IMP cyclohydrolase can include, for example, the AICAR formyltransferase/IMP cyclohydrolase genes or AICAR formyltransferases/IMP cyclohydrolases exemplified above and conservative variants thereof.

The “specific mutation” is not particularly limited, so long as the mutation improves an objective substance-producing ability of the microorganism. The “specific mutation” may be, for example, a mutation for reducing the activity of AICAR formyltransferase/IMP cyclohydrolase. The “specific mutation” may also be, for example, a mutation for increasing the intracellular concentration of AICAR.

Specific examples of the “specific mutation” can include a mutation that the serine residue at position 37 (S37) of the encoded AICAR formyltransferase/IMP cyclohydrolase is replaced with another amino acid residue.

In the mutation at “S37”, the amino acid residue after the modification may be any amino acid residue other than the amino acid residue before the modification, which is at least other than a serine residue, so long as the mutation improves an objective substance-producing ability of the microorganism. Examples of the amino acid residue after modification can include K (Lys), R (Arg), H (His), A (Ala), V (Val), L (Leu), I (Ile), G (Gly), T (Thr), P (Pro), F (Phe), W (Trp), Y (Tyr), C (Cys), M (Met), D (Asp), E (Glu), N (Asn), and Q (Gln). Particular examples of the amino acid residue after modification can include F (Phe). That is, particular examples of the “specific mutation” can include a mutation for replacing S37 with F (S37F mutation).

The term “S37” in an arbitrary wild-type AICAR formyltransferase/IMP cyclohydrolase can refer to an amino acid residue corresponding to the serine residue at position 37 of the amino acid sequence shown as SEQ ID NO: 135. The descriptions regarding the mutations at “L198” or “E199” for OMT, such as those for defining the absolute positions thereof, can be applied mutatis mutandis to the mutation at “S37” for AICAR formyltransferase/IMP cyclohydrolase, provided that the amino acid sequence shown in SEQ ID NO: 135″ is used as the reference sequence of the wild-type protein.

A mutant AICAR formyltransferase/IMP cyclohydrolase gene can be obtained by, for example, modifying a wild-type AICAR formyltransferase/IMP cyclohydrolase gene so that AICAR formyltransferase/IMP cyclohydrolase encoded thereby has the “specific mutation”. The wild-type AICAR formyltransferase/IMP cyclohydrolase gene to be modified can be obtained by, for example, cloning from an organism having the wild-type AICAR formyltransferase/IMP cyclohydrolase gene, or chemical synthesis. Alternatively, a mutant AICAR formyltransferase/IMP cyclohydrolase gene can also be obtained without using a wild-type AICAR formyltransferase/IMP cyclohydrolase gene. For example, a mutant AICAR formyltransferase/IMP cyclohydrolase gene may be directly obtained by, for example, cloning from an organism having the mutant AICAR formyltransferase/IMP cyclohydrolase gene, or chemical synthesis. The obtained mutant AICAR formyltransferase/IMP cyclohydrolase gene may be used as it is, or may be further modified before use. Genes can be modified by using a known method. For example, an objective mutation can be introduced into a target site of DNA by the site-specific mutagenesis method. The wild-type AICAR formyltransferase/IMP cyclohydrolase gene to be modified or the mutant AICAR formyltransferase/IMP cyclohydrolase gene may or may not be derived from the host, such as a microorganism from which the microorganism as described herein is derived.

Methods for modifying a microorganism so that the AICAR formyltransferase/IMP cyclohydrolase gene has the “specific mutation” are not particularly limited. The phrase “a microorganism is modified so that a gene encoding AICAR formyltransferase/IMP cyclohydrolase has the “specific mutation”” may specifically mean that the microorganism is modified so as to have a mutant AICAR formyltransferase/IMP cyclohydrolase gene instead of a native wild-type AICAR formyltransferase/IMP cyclohydrolase gene. The phrase “a microorganism has a mutant AICAR formyltransferase/IMP cyclohydrolase gene instead of a native wild-type AICAR formyltransferase/IMP cyclohydrolase gene” can mean that the microorganism has the mutant AICAR formyltransferase/IMP cyclohydrolase gene while it no longer has the normally-functional native wild-type AICAR formyltransferase/IMP cyclohydrolase gene, that is, the native wild-type AICAR formyltransferase/IMP cyclohydrolase gene has been modified so as not to normally function. It is sufficient that the native wild-type AICAR formyltransferase/IMP cyclohydrolase gene has been modified in such a manner that an objective substance-producing ability of the microorganism is improved. The phrase “native wild-type AICAR formyltransferase/IMP cyclohydrolase gene” can refer to a wild-type AICAR formyltransferase/IMP cyclohydrolase gene inherently present in the microorganism. A microorganism can be modified so that the AICAR formyltransferase/IMP cyclohydrolase gene has the “specific mutation” by, for example, introducing a mutant AICAR formyltransferase/IMP cyclohydrolase gene into the microorganism. In such a case, the native wild-type AICAR formyltransferase/IMP cyclohydrolase gene on the chromosome or the like of the microorganism should be modified, e.g. disrupted or deleted, in such a manner that an objective substance-producing ability of the microorganism is improved in combination with the introduction of the mutant AICAR formyltransferase/IMP cyclohydrolase gene. For example, the native wild-type AICAR formyltransferase/IMP cyclohydrolase gene may be replaced with the mutant AICAR formyltransferase/IMP cyclohydrolase gene, or may be disrupted or deleted independently from the introduction of the mutant AICAR formyltransferase/IMP cyclohydrolase gene. Alternatively, the microorganism can also be modified so that the AICAR formyltransferase/IMP cyclohydrolase gene has the “specific mutation” by, for example, introducing the “specific mutation” into a wild-type AICAR formyltransferase/IMP cyclohydrolase gene, such as the native wild-type AICAR formyltransferase/IMP cyclohydrolase gene, on the chromosome or the like of the microorganism. A mutation can be introduced into a gene on a chromosome or the like by, for example, natural mutation, mutagenesis treatment, or genetic engineering.

The protein of which the activity is to be modified can be appropriately chosen depending on the type of the biosynthesis pathway via which an objective substance is produced in the method as described herein and on the types and activities of the proteins inherently possessed by the microorganism. For example, when vanillin is produced by bioconversion of protocatechuic acid, it may be preferable to enhance the activity or activities of one or more of OMT, ACAR, PPT, and the protocatechuic acid uptake system. Also, when vanillin is produced by bioconversion of protocatechualdehyde, it may be preferable to enhance the activity of OMT.

The genes and proteins used for breeding a microorganism having an objective substance-producing ability may have, for example, the above-exemplified or other known nucleotide sequences and amino acid sequences, respectively. Also, the genes and proteins used for breeding a microorganism having an objective substance-producing ability may be conservative variants of the genes and proteins exemplified above, such as genes and proteins having the above-exemplified or other known nucleotide sequences and amino acid sequences, respectively. Specifically, for example, the genes used for breeding a microorganism having an objective substance-producing ability may each be a gene encoding a protein having the amino acid sequence exemplified above or the amino acid sequence of a known protein, but including substitution, deletion, insertion, and/or addition of one or several some amino acid residues at one or several positions, so long as the original function of the protein, such as enzymatic activity, transporter activity, etc., is maintained. Furthermore, for example, the genes used for breeding a microorganism having an objective substance-producing ability may each be a gene encoding a protein having an amino acid sequence showing a homology of, for example, 50% or more, 65% or more, 80% or more, 90% or more, 95% or more, 97% or more, or 99% or more, to the total amino acid sequence of the amino acid sequence exemplified above or the amino acid sequence of a known protein, so long as the original function of the protein is maintained. As for conservative variants of genes and proteins, the descriptions concerning conservative variants of the SAM cycle enzyme gene and SAM cycle enzyme described herein can be applied mutatis mutandis.

<1-2> Increase in SAM Cycle Enzyme Activity

The microorganism as described herein has been modified so that the activity of an SAM cycle enzyme is increased. Specifically, the microorganism has been modified so that the activity of an SAM cycle enzyme is increased as compared with a strain of a non-modified microorganism. By modifying a microorganism so that the activity of an SAM cycle enzyme is increased, an objective substance-producing ability of the microorganism can be improved, that is, the production of an objective substance by using the microorganism can be increased. Also, by modifying a microorganism so that the activity of an SAM cycle enzyme is increased, an ability of the microorganism for generating or regenerating SAM may possibly be improved. That is, specifically, an increase in an objective substance-producing ability of a microorganism may be due to an increase in an ability of the microorganism to generate or regenerate SAM.

The microorganism as described herein can be obtained by modifying a microorganism having an objective substance-producing ability so that the activity of an SAM cycle enzyme is increased. The microorganism can also be obtained by modifying a microorganism so that the activity of an SAM cycle enzyme is increased, and then imparting an objective substance-producing ability to the microorganism or enhancing an objective substance-producing ability of the microorganism. In addition, the microorganism may acquire an objective substance-producing ability as a result of a modification that results in increasing the activity of an SAM cycle enzyme, or as a result of a combination of a modification that results in increasing the activity of an SAM cycle enzyme and other modification(s) for imparting or enhancing an objective substance-producing ability. The modifications for constructing the microorganism can be performed in an arbitrary order.

The term “S-adenosylmethionine cycle enzyme (SAM cycle enzyme)” can refer to an enzyme that is involved in the SAM cycle. A gene encoding a SAM cycle enzyme can also be referred to as a “SAM cycle enzyme gene”. The SAM cycle enzyme can be S-adenosyl-L-homocysteine hydrolase, methionine synthase, methionine adenosyltransferase, or 5,10-methylenetetrahydrofolate reductase. In an embodiment, the SAM cycle enzyme may be methionine adenosyltransferase, methionine synthase, or 5,10-methylenetetrahydrofolate reductase. In such an embodiment, the activity of S-adenosyl-L-homocysteine hydrolase may additionally be increased. The activity of one SAM cycle enzyme may be increased, or the activities of two or more of the SAM cycle enzymes may be increased.

The term “S-adenosyl-L-homocysteine hydrolase” can refer to a protein that has the activity of catalyzing the reaction of hydrolyzing S-adenosyl-L-homocysteine (SAH) to generate L-homocysteine and adenosine (EC 3.3.1.1). This activity can also be referred to as an “S-adenosyl-L-homocysteine hydrolase activity”. S-adenosyl-L-homocysteine hydrolase can also be referred to as “adenosylhomocysteinase”. A gene encoding an S-adenosyl-L-homocysteine hydrolase can also be referred to as an “S-adenosyl-L-homocysteine hydrolase gene”. Examples of an S-adenosyl-L-homocysteine hydrolase can include an SahH protein, which is encoded by an sahH gene. Examples of an S-adenosyl-L-homocysteine hydrolase such as the SahH protein can include those native to various organisms such as yeast, Streptomyces bacteria, and coryneform bacteria. Specific examples of an S-adenosyl-L-homocysteine hydrolase can include the SahH protein native to C. glutamicum. The nucleotide sequence of the sahH gene (NCgl0719) native to the C. glutamicum ATCC 13869 strain is shown as SEQ ID NO: 144, and the amino acid sequence of the SahH protein encoded by this gene is shown as SEQ ID NO: 145.

The term “methionine synthase” can refer to a protein that has the activity of catalyzing the reaction of methylating L-homocysteine to generate L-methionine in the presence of a methyl group donor (EC 2.1.1.13, EC 2.1.1.14, etc.). This activity can also be referred to as a “methionine synthase activity”. A gene encoding a methionine synthase can also be referred to as a “methionine synthase gene”. Examples of the methyl group donor used by methionine synthase can include 5-methyltetrahydropteroyl-mono-L-glutamate (synonym: 5-methyltetrahydrofolate; 5-MTHF) and those having two more L-glutamate residues, such as 5-methyltetrahydropteroyl-tri-L-glutamate. Examples of a methionine synthase can include MetE and MetH proteins, which are encoded by metE and metH genes, respectively. MetE protein may be a vitamin-B12-independent methionine synthase. MetH protein may be a vitamin-B12-dependent methionine synthase. Examples of a methionine synthase such as the MetE and MetH proteins can include those native to various organisms such as Enterobacteriaceae bacteria and coryneform bacteria. Specific examples of methionine synthase can include the MetE and MetH proteins native to E. coli. The nucleotide sequences of the metE and metH genes native to the E. coli K-12 MG1655 are shown as SEQ ID NOS: 165 and 167, respectively, and the amino acid sequences of the proteins encoded by these genes are shown as SEQ ID NOS: 166 and 168, respectively. The nucleotide sequence of the metH gene (cg1701) native to the C. glutamicum ATCC 13032 strain is shown as SEQ ID NO: 169, and the amino acid sequence of the MetH protein encoded by this gene is shown as SEQ ID NO: 170. Incidentally, coryneform bacteria such as Corynebacterium glutamicum has NCgl2048 gene, which encodes a protein homologous to both MetE and MetH proteins native to E. coli. While the protein encoded by NCgl2048 gene is annotated as methionine synthase in some databases, this protein is excluded from “methionine synthase” as referred to herein.

The term “methionine adenosyltransferase” can refer to a protein that has the activity of catalyzing the reaction of converting L-methionine into SAM in the presence of ATP (EC 2.5.1.6). This activity can also be referred to as a “methionine adenosyltransferase activity”. A gene encoding a methionine adenosyltransferase can also be referred to as “methionine adenosyltransferase gene”. Examples of a methionine adenosyltransferase can include an MetK protein, which is encoded by an metK gene. Examples of a methionine adenosyltransferase such as the MetK protein can include those native to various organisms such as Enterobacteriaceae bacteria and coryneform bacteria. Specific examples of a methionine adenosyltransferase can include MetK protein native to C. glutamicum. The nucleotide sequence of the metK gene (NCgl1541) native to the C. glutamicum ATCC 13869 strain is shown as SEQ ID NO: 161, and the amino acid sequence of the MetK protein encoded by this gene is shown as SEQ ID NO: 162.

The term “5,10-methylenetetrahydrofolate reductase” can refer to a protein that has the activity of catalyzing the reaction of reducing 5,10-methylenetetrahydrofolate to generate 5-methyltetrahydrofolate (5-MTHF) in the presence of an electron donor (EC 1.5.1.20). This activity can also be referred to as a “5,10-methylenetetrahydrofolate reductase activity”. A gene encoding a 5,10-methylenetetrahydrofolate reductase can also be referred to as “5,10-methylenetetrahydrofolate reductase gene”. Examples of a 5,10-methylenetetrahydrofolate reductase can include an MetF protein, which is encoded by an metF gene. Examples of the electron donor can include NADH and NADPH. Examples of a 5,10-methylenetetrahydrofolate reductase such as the MetF protein can include those native to various organisms such as yeast, Enterobacteriaceae bacteria, and coryneform bacteria. Specific examples of a 5,10-methylenetetrahydrofolate reductase can include the MetF proteins native to C. glutamicum and S. cerevisiae. The nucleotide sequence of the metF gene (NCgl2091) native to the C. glutamicum ATCC 13869 strain is shown as SEQ ID NO: 183, and the amino acid sequence of the MetF protein encoded by this gene is shown as SEQ ID NO: 184. The nucleotide sequence of the metF gene (MET13) native to the S. cerevisiae S288c strain is shown as SEQ ID NO: 173, and the amino acid sequence of the MetF protein encoded by this gene is shown as SEQ ID NO: 174. Specific examples of 5,10-methylenetetrahydrofolate reductase also can include a partial MetF protein native to C. glutamicum used in the Examples section. The nucleotide sequence of a partial metF gene encoding this partial MetF protein is shown as SEQ ID NO: 171, and the amino acid sequence of this partial MetF protein is shown as SEQ ID NO: 172. The terms “metF gene” and “MetF protein” can include these partial metF gene and MetF protein, as well as full-length ones.

That is, the SAM cycle enzyme gene may be, for example, a gene having or including the nucleotide sequence shown as SEQ ID NOs: 144, 161, 165, 167, 169, 171, 173, or 183. Also, the SAM cycle enzyme may be, for example, a protein having or including the amino acid sequence shown as SEQ ID NO: 145, 162, 166, 168, 170, 172, 174, or 184.

The SAM cycle enzyme gene may be a variant of any of the SAM cycle enzyme genes exemplified above, such as the sahH, metE, metH, metK, and metF genes, so long as the original function thereof is maintained. Similarly, the SAM cycle enzyme may be a variant of any of the SAM cycle enzymes exemplified above, such as the SahH, MetE, MetH, MetK, and MetF proteins, so long as the original function thereof is maintained. A variant that maintains the original function thereof can also be referred to as a “conservative variant”. A gene defined with the above-mentioned gene name and a protein defined with the above-mentioned protein name can include not only the genes and proteins exemplified above, respectively, but also can include conservative variants thereof. Namely, for example, the term “metK gene (or NCgl1541 gene)” can includes not only the metK gene exemplified above, such as the metK gene having the nucleotide sequence shown as SEQ ID NO: 161, but also can include conservative variants thereof. Similarly, the term “MetK protein (or NCgl1541 protein)” can include not only the MetK protein exemplified above, such as the MetK protein having the amino acid sequence shown as SEQ ID NO: 162, but also can include conservative variants thereof. Examples of the conservative variants can include, for example, homologues and artificially modified versions of the genes and proteins exemplified above.

The phrase “the original function is maintained” means that a variant of the gene or protein has a function, such as activity or property corresponding to the function, such as activity or property, of the original gene or protein. The phrase “the original function is maintained” in reference to a gene can mean that a variant of the gene encodes a protein that maintains the original function. That is, the phrase “the original function is maintained” in reference to the SAM cycle enzyme gene can mean that the variant of the gene encodes a SAM cycle enzyme. The phrase “the original function is maintained” in reference to the SAM cycle enzyme can mean that the variant of the protein has the corresponding SAM cycle enzyme activity, such as the S-adenosyl-L-homocysteine hydrolase activity for S-adenosyl-L-homocysteine hydrolase; the methionine synthase activity for methionine synthase; the methionine adenosyltransferase activity for methionine adenosyltransferase; and the 5,10-methylenetetrahydrofolate reductase activity for 5,10-methylenetetrahydrofolate reductase.

The S-adenosyl-L-homocysteine hydrolase activity can be measured by, for example, incubating the enzyme with a substrate, such as S-adenosyl-L-homocysteine and DTNB (5,5′-Dithiobis(2-nitrobenzoic acid), and measuring the product, such as homocysteine-dependent generation of TNB (5-Mercapto-2-nitrobenzoic acid) on the basis of absorbance at 412 nm (J Mol Microbiol Biotechnol 2008, 15: 277-286).

The methionine synthase activity can be measured by, for example, incubating the enzyme with a substrate, such as L-homocysteine in the presence of a methyl group donor, and measuring the enzyme- and substrate-dependent generation of L-methionine.

The methionine adenosyltransferase activity can be measured by, for example, incubating the enzyme with a substrate, such as L-serine, and measuring the enzyme- and substrate-dependent generation of pyruvic acid or ammonia.

The 5,10-methylenetetrahydrofolate reductase activity can be measured by, for example, incubating the enzyme with a substrate, such as 5,10-methylenetetrahydrofolate, in the presence of an electron donor, and measuring the enzyme- and substrate-dependent generation of 5-MTHF.

The SAM cycle enzyme can have the corresponding SAM cycle enzyme activity, that is, the S-adenosyl-L-homocysteine hydrolase activity for S-adenosyl-L-homocysteine hydrolase; the methionine synthase activity for methionine synthase; the methionine adenosyltransferase activity for methionine adenosyltransferase; and the 5,10-methylenetetrahydrofolate reductase activity for 5,10-methylenetetrahydrofolate reductase, which is measured under at least one appropriate condition. In other words, it is sufficient that the microorganism is modified so that the activity of an SAM cycle enzyme is increased when the activity is measured under at least one appropriate condition. Incidentally, it is also sufficient that all the other proteins referred to herein can have the respective activities that are each measured under at least one appropriate condition.

Hereafter, examples of the conservative variants will be explained.

Homologues of the SAM cycle enzyme gene or homologues of the SAM cycle enzymes can be easily determined from public databases by, for example, BLAST search or FASTA search, using any of the nucleotide sequences of the SAM cycle enzyme genes exemplified above or any of the amino acid sequences of the SAM cycle enzymes exemplified above as a query sequence. Furthermore, homologues of the SAM cycle enzyme gene can be obtained by, for example, PCR using a chromosome of an organism such as coryneform bacteria as the template, and oligonucleotides prepared on the basis of any of the nucleotide sequences of the SAM cycle enzyme genes exemplified above as primers.

The SAM cycle enzyme gene may be a gene encoding a protein having any of the aforementioned amino acid sequences, such as the amino acid sequence shown as SEQ ID NO: 145, 162, 166, 168, 170, 172, 174, or 184, including substitution, deletion, insertion, and/or addition of one or several amino acid residues at one or several positions, so long as the original function is maintained. For example, the encoded protein may have an extended or deleted N-terminus and/or C-terminus. Although the number meant by the phrase “one or several” may differ depending on the positions of amino acid residues in the three-dimensional structure of the protein or the types of amino acid residues, specifically, it can be, for example, 1 to 50, 1 to 40, 1 to 30, 1 to 20, 1 to 10, 1 to 5, or 1 to 3.

The aforementioned substitution, deletion, insertion, and/or addition of one or several amino acid residues are each a conservative mutation that maintains the original function of the protein. Typical examples of the conservative mutation are conservative substitutions. The conservative substitution is a mutation wherein substitution takes place mutually among Phe, Trp, and Tyr, if the substitution site is an aromatic amino acid; among Leu, Ile, and Val, if it is a hydrophobic amino acid; between Gln and Asn, if it is a polar amino acid; among Lys, Arg, and His, if it is a basic amino acid; between Asp and Glu, if it is an acidic amino acid; and between Ser and Thr, if it is an amino acid having a hydroxyl group. Examples of substitutions considered as conservative substitutions can include, specifically, substitution of Ser or Thr for Ala, substitution of Gln, His, or Lys for Arg, substitution of Glu, Gln, Lys, His, or Asp for Asn, substitution of Asn, Glu, or Gln for Asp, substitution of Ser or Ala for Cys, substitution of Asn, Glu, Lys, His, Asp, or Arg for Gln, substitution of Gly, Asn, Gln, Lys, or Asp for Glu, substitution of Pro for Gly, substitution of Asn, Lys, Gln, Arg, or Tyr for His, substitution of Leu, Met, Val, or Phe for Ile, substitution of Ile, Met, Val, or Phe for Leu, substitution of Asn, Glu, Gln, His, or Arg for Lys, substitution of Ile, Leu, Val, or Phe for Met, substitution of Trp, Tyr, Met, Ile, or Leu for Phe, substitution of Thr or Ala for Ser, substitution of Ser or Ala for Thr, substitution of Phe or Tyr for Trp, substitution of His, Phe, or Trp for Tyr, and substitution of Met, Ile, or Leu for Val. Furthermore, such substitution, deletion, insertion, addition, or the like of amino acid residues as mentioned above can include a naturally occurring mutation due to an individual difference, or a difference of species of the organism from which the gene is derived (mutant or variant).

Furthermore, the SAM cycle enzyme gene may be a gene encoding a protein having an amino acid sequence showing a homology of, for example, 50% or more, 65% or more, 80% or more, 90% or more, 95% or more, 97% or more, or 99% or more, to the total amino acid sequence of any of the aforementioned amino acid sequences, so long as the original function is maintained. In addition, in this specification, “homology” is equivalent to “identity”.

Furthermore, the SAM cycle enzyme gene may be a gene, such as a DNA, that is able to hybridize under stringent conditions with a probe that can be prepared from any of the aforementioned nucleotide sequences, for example the nucleotide sequence shown as SEQ ID NO: 144, 161, 165, 167, 169, 171, 173, or 183, such as a sequence complementary to the whole sequence or a partial sequence of any of the aforementioned nucleotide sequences, so long as the original function is maintained. The “stringent conditions” can refer to conditions under which a so-called specific hybrid is formed, and a non-specific hybrid is not formed. Examples of the stringent conditions can include those under which highly homologous DNAs hybridize to each other, for example, DNAs not less than 50%, 65%, 80%, 90%, 95%, 97%, or 99% homologous, hybridize to each other, and DNAs less homologous than the above do not hybridize to each other, or conditions of washing of typical Southern hybridization, that is, conditions of washing once, or 2 or 3 times, at a salt concentration and temperature corresponding to 1×SSC, 0.1% SDS at 60° C.; 0.1×SSC, 0.1% SDS at 60° C.; or 0.1×SSC, 0.1% SDS at 68° C.

The probe used for the aforementioned hybridization may be a part of a sequence that is complementary to the gene as described above. Such a probe can be prepared by PCR using oligonucleotides prepared on the basis of a known gene sequence as primers and a DNA fragment containing any of the aforementioned genes as a template. As the probe, for example, a DNA fragment having a length of about 300 bp can be used. When a DNA fragment having a length of about 300 bp is used as the probe, in particular, the washing conditions of the hybridization may be, for example, 50° C., 2×SSC and 0.1% SDS.

Furthermore, since properties concerning degeneracy of codons can change depending on the host, the SAM cycle enzyme gene can include substitution of respective equivalent codons for arbitrary codons. That is, the SAM cycle enzyme gene may be a variant of any of the SAM cycle enzyme genes exemplified above due to the degeneracy of the genetic code. For example, the SAM cycle enzyme gene may be modified so that it has optimal codons according to codon frequencies in the chosen host.

The percentage of the sequence identity between two sequences can be determined by, for example, using a mathematical algorithm. Non-limiting examples of such a mathematical algorithm can include the algorithm of Myers and Miller (1988) CABIOS 4:11-17, the local homology algorithm of Smith et al (1981) Adv. Appl. Math. 2:482, the homology alignment algorithm of Needleman and Wunsch (1970) J. Mol. Biol. 48:443-453, the method for searching homology of Pearson and Lipman (1988) Proc. Natl. Acad. Sci. 85:2444-2448, and a modified version of the algorithm of Karlin and Altschul (1990) Proc. Natl. Acad. Sci. USA 87:2264, such as that described in Karlin and Altschul (1993) Proc. Natl. Acad. Sci. USA 90:5873-5877.

By using a program based on such a mathematical algorithm, sequence comparison, i.e. alignment, for determining the sequence identity can be performed. The program can be appropriately executed by a computer. Examples of such a program can include, but are not limited to, CLUSTAL of PC/Gene program (available from Intelligenetics, Mountain View, Calif.), ALIGN program (Version 2.0), and GAP, BESTFIT, BLAST, FASTA, and TFASTA of Wisconsin Genetics Software Package, Version 8 (available from Genetics Computer Group (GCG), 575 Science Drive, Madison, Wis., USA). Alignment using these programs can be performed by using, for example, initial parameters. The CLUSTAL program is well described in Higgins et al. (1988) Gene 73:237-244 (1988), Higgins et al. (1989) CABIOS 5:151-153, Corpet et al. (1988) Nucleic Acids Res. 16:10881-90, Huang et al. (1992) CABIOS 8:155-65, and Pearson et al. (1994) Meth. Mol. Biol. 24:307-331.

In order to obtain a nucleotide sequence homologous to a target nucleotide sequence, in particular, for example, BLAST nucleotide search can be performed by using BLASTN program with score of 100 and word length of 12. In order to obtain an amino acid sequence homologous to a target protein, in particular, for example, BLAST protein search can be performed by using BLASTX program with score of 50 and word length of 3. See ncbi.nlm.nih.gov for BLAST nucleotide search and BLAST protein search. In addition, Gapped BLAST (BLAST 2.0) can be used in order to obtain an alignment including gap(s) for the purpose of comparison. In addition, PSI-BLAST can be used in order to perform repetitive search for detecting distant relationships between sequences. See Altschul et al. (1997) Nucleic Acids Res. 25:3389 for Gapped BLAST and PSI-BLAST. When using BLAST, Gapped BLAST, or PSI-BLAST, initial parameters of each program (e.g. BLASTN for nucleotide sequences, and BLASTX for amino acid sequences) can be used. Alignment can also be manually performed.

The sequence identity between two sequences is calculated as the ratio of residues matching in the two sequences when aligning the two sequences so as to fit maximally with each other. The term “identity” between amino acid sequences may specifically mean an identity calculated by blastp with default scoring parameters (i.e. Matrix, BLOSUM62; Gap Costs, Existence=11, Extension=1; Compositional Adjustments, Conditional compositional score matrix adjustment), unless otherwise stated. The term “identity” between nucleotide sequences may specifically mean an identity calculated by blastn with default scoring parameters (i.e. Match/Mismatch Scores=1, −2; Gap Costs=Linear), unless otherwise stated.

The aforementioned descriptions concerning conservative variants of the genes and proteins can be applied mutatis mutandis to variants of arbitrary proteins such as objective substance biosynthesis enzymes and genes encoding them.

<1-3> Methods for Increasing Activity of Protein

Hereinafter, the methods for increasing the activity of a protein such as the SAM cycle enzyme will be explained.

The phrase “the activity of a protein is increased” can mean that the activity of the protein is increased as compared with a non-modified strain, that is, as compared with a strain of a non-modified microorganism. Specifically, the phrase “the activity of a protein is increased” can mean that the activity of the protein per cell is increased as compared with that of a non-modified strain. The term “non-modified strain” or “strain of a non-modified microorganism” can refer to a control strain that has not been modified so that the activity of an objective protein is increased. Examples of the non-modified strain can include a wild-type strain and parent strain. Specific examples of the non-modified strain can include the respective type strains of the species of microorganisms. Specific examples of the non-modified strain can also include strains exemplified above in relation to the description of microorganisms. That is, in an embodiment, the activity of a protein may be increased as compared with a type strain, that is, the type strain of the species to which the microorganism as described herein belongs. In another embodiment, the activity of a protein may also be increased as compared with the C. glutamicum ATCC 13869 strain. In another embodiment, the activity of a protein may also be increased as compared with the C. glutamicum ATCC 13032 strain. In another embodiment, the activity of a protein may also be increased as compared with the E. coli K-12 MG1655 strain. The phrase “the activity of a protein is increased” may also be expressed as “the activity of a protein is enhanced”. More specifically, the phrase “the activity of a protein is increased” can mean that the number of molecules of the protein per cell is increased, and/or the function of each molecule of the protein is increased, as compared with those of a non-modified strain. That is, the term “activity” in the phrase “the activity of a protein is increased” is not limited to the catalytic activity of the protein, but can also mean the transcription amount of a gene encoding the protein, that is, the amount of mRNA, or the translation amount of a gene encoding the protein, that is, the amount of the protein. Furthermore, the phrase “the activity of a protein is increased” can include not only when the activity of an objective protein is increased in a strain inherently having the activity of the objective protein, but also when the activity of an objective protein is imparted to a strain not inherently having the activity of the objective protein. Furthermore, so long as the activity of the protein is eventually increased, the activity of an objective protein inherently present in a host may be attenuated and/or eliminated, and then an appropriate type of the objective protein may be imparted to the host.

The degree of the increase in the activity of a protein is not particularly limited, so long as the activity of the protein is increased as compared with a non-modified strain. The activity of the protein may be increased to, for example, 1.2 times or more, 1.5 times or more, 2 times or more, or 3 times or more of that of a non-modified strain. Furthermore, when the non-modified strain does not have the activity of the objective protein, it is sufficient that the protein is produced as a result of introduction of the gene encoding the protein, and for example, the protein may be produced to such an extent that the activity thereof can be measured.

The modification for increasing the activity of a protein can be attained by, for example, increasing the expression of a gene encoding the protein. The phrase “the expression of a gene is increased” can mean that the expression of the gene is increased as compared with a non-modified strain, such as a wild-type strain and parent strain. Specifically, the phrase “the expression of a gene is increased” can mean that the expression amount of the gene per cell is increased as compared with that of a non-modified strain. More specifically, the phrase “the expression of a gene is increased” can mean that the transcription amount of the gene, that is, the amount of mRNA, is increased, and/or the translation amount of the gene, that is, the amount of the protein expressed from the gene, is increased. The phrase “the expression of a gene is increased” can also be referred to as “the expression of a gene is enhanced”. The expression of a gene may be increased to, for example, 1.2 times or more, 1.5 times or more, 2 times or more, or 3 times or more of that of a non-modified strain. Furthermore, the phrase “the expression of a gene is increased” can include not only when the expression amount of an objective gene is increased in a strain that inherently expresses the objective gene, but also when the gene is introduced into a strain that does not inherently express the objective gene, and is expressed therein. That is, the phrase “the expression of a gene is increased” may also mean, for example, that an objective gene is introduced into a strain that does not possess the gene, and is expressed therein.

The expression of a gene can be increased by, for example, increasing the copy number of the gene.

The copy number of a gene can be increased by introducing the gene into the chromosome of a host. A gene can be introduced into a chromosome by, for example, using homologous recombination (Miller, J. H., Experiments in Molecular Genetics, 1972, Cold Spring Harbor Laboratory). Examples of the gene transfer method utilizing homologous recombination can include, for example, a method of using a linear DNA such as Red-driven integration (Datsenko, K. A., and Wanner, B. L., Proc. Natl. Acad. Sci. USA, 97:6640-6645 (2000)), a method of using a plasmid containing a temperature sensitive replication origin, a method of using a plasmid capable of conjugative transfer, a method of using a suicide vector not having a replication origin that functions in a host, and a transduction method using a phage. Only one copy of a gene may be introduced, or two or more copies of a gene may be introduced. For example, by performing homologous recombination using a sequence which is present in multiple copies on a chromosome as a target, multiple copies of a gene can be introduced into the chromosome. Examples of such a sequence which is present in multiple copies on a chromosome can include repetitive DNAs, and inverted repeats located at the both ends of a transposon. Alternatively, homologous recombination may be performed by using an appropriate sequence on a chromosome, such as a gene, unnecessary for the production of an objective substance as a target. Furthermore, a gene can also be randomly introduced into a chromosome by using a transposon or Mini-Mu (Japanese Patent Laid-open (Kokai) No. 2-109985, U.S. Pat. No. 5,882,888, EP 805867 B1).

Introduction of a target gene into a chromosome can be confirmed by Southern hybridization using a probe having a sequence complementary to the whole gene or a part thereof, PCR using primers prepared on the basis of the sequence of the gene, or the like.

Furthermore, the copy number of a gene can also be increased by introducing a vector containing the gene into a host. For example, the copy number of a target gene can be increased by ligating a DNA fragment containing the target gene with a vector that functions in a host to construct an expression vector of the gene, and transforming the host with the expression vector. The DNA fragment containing the target gene can be obtained by, for example, PCR using the genomic DNA of a microorganism having the target gene as the template. As the vector, a vector autonomously replicable in the cell of the host can be used. The vector can be a multi-copy vector. Furthermore, the vector can have a marker such as an antibiotic resistance gene for selection of transformant. Furthermore, the vector can have a promoter and/or terminator for expressing the introduced gene. The vector may be, for example, a vector derived from a bacterial plasmid, a vector derived from a yeast plasmid, a vector derived from a bacteriophage, cosmid, phagemid, or the like. Specific examples of a vector autonomously replicable in Enterobacteriaceae bacteria such as Escherichia coli can include, for example, pUC19, pUC18, pHSG299, pHSG399, pHSG398, pBR322, pSTV29 (all of these are available from Takara Bio), pACYC184, pMW219 (NIPPON GENE), pTrc99A (Pharmacia), pPROK series vectors (Clontech), pKK233-2 (Clontech), pET series vectors (Novagen), pQE series vectors (QIAGEN), pCold TF DNA (Takara Bio), pACYC series vectors, and the broad host spectrum vector RSF1010. Specific examples of a vector autonomously replicable in coryneform bacteria can include, for example, pHM1519 (Agric. Biol. Chem., 48, 2901-2903 (1984)); pAM330 (Agric. Biol. Chem., 48, 2901-2903 (1984)); plasmids obtained by improving these and having a drug resistance gene; plasmid pCRY30 described in Japanese Patent Laid-open (Kokai) No. 3-210184; plasmids pCRY21, pCRY2KE, pCRY2KX, pCRY31, pCRY3KE, and pCRY3KX described in Japanese Patent Laid-open (Kokai) No. 2-72876 and U.S. Pat. No. 5,185,262; plasmids pCRY2 and pCRY3 described in Japanese Patent Laid-open (Kokai) No. 1-191686; pAJ655, pAJ611, and pAJ1844 described in Japanese Patent Laid-open (Kokai) No. 58-192900; pCG1 described in Japanese Patent Laid-open (Kokai) No. 57-134500; pCG2 described in Japanese Patent Laid-open (Kokai) No. 58-35197; pCG4 and pCG11 described in Japanese Patent Laid-open (Kokai) No. 57-183799; pVK7 described in Japanese Patent Laid-open (Kokai) No. 10-215883; pVK9 described in WO2007/046389; pVS7 described in WO2013/069634; and pVC7 described in Japanese Patent Laid-open (Kokai) No. 9-070291.

When a gene is introduced, it is sufficient that the gene is able to be expressed by the chosen host. Specifically, it is sufficient that the gene is present in a host so that it is expressed under the control of a promoter that functions in the host. The term “promoter that functions in a host” can refer to a promoter that shows a promoter activity in the host. The promoter may be a promoter derived from the host, or may be a heterogenous promoter. The promoter may be the native promoter of the gene to be introduced, or a promoter of another gene. As the promoter, for example, such a stronger promoter as described herein may also be used.

A terminator for termination of gene transcription may be located downstream of the gene. The terminator is not particularly limited so long as it functions in the chosen host. The terminator may be a terminator derived from the host, or may be a heterogenous terminator. The terminator may be the native terminator of the gene to be introduced, or a terminator of another gene. Specific examples of the terminator can include, for example, T7 terminator, T4 terminator, fd phage terminator, tet terminator, and trpA terminator.

Vectors, promoters, and terminators available in various microorganisms are disclosed in detail in “Fundamental Microbiology Vol. 8, Genetic Engineering, KYORITSU SHUPPAN CO., LTD, 1987”, and those can be used.

Furthermore, when two or more of genes are introduced, it is sufficient that the genes each are expressibly harbored by a host. For example, all the genes may be carried by a single expression vector or a chromosome. Furthermore, the genes may be separately carried by two or more expression vectors, or separately carried by a single or two or more expression vectors and a chromosome. An operon made up of two or more genes may also be introduced. When “introducing two or more genes”, for example, the respective genes encoding two or more kinds of proteins, such as enzymes; the respective genes encoding two or more subunits that make up a single protein complex, such as an enzyme complex, or a combination of these can be introduced.

The gene to be introduced is not particularly limited so long as it encodes a protein that functions in the host. The gene to be introduced may be a gene derived from the host, or may be a heterogenous gene. The gene to be introduced can be obtained by, for example, PCR using primers designed on the basis of the nucleotide sequence of the gene, and using the genomic DNA of an organism having the gene, a plasmid carrying the gene, or the like as a template. The gene to be introduced may also be totally synthesized, for example, on the basis of the nucleotide sequence of the gene (Gene, 60(1), 115-127 (1987)). The obtained gene can be used as it is, or after being modified as required. That is, a variant of a gene may be obtained by modifying the gene. A gene can be modified by a known technique. For example, an objective mutation can be introduced into an objective site of DNA by the site-specific mutation method. That is, the coding region of a gene can be modified by the site-specific mutation method so that a specific site of the encoded protein includes substitution, deletion, insertion, and/or addition of amino acid residues. Examples of the site-specific mutation method can include the method utilizing PCR (Higuchi, R., 61, in PCR Technology, Erlich, H. A. Eds., Stockton Press (1989); Carter, P., Meth. in Enzymol., 154, 382 (1987)), and the method utilizing phage (Kramer, W. and Frits, H. J., Meth. in Enzymol., 154, 350 (1987); Kunkel, T. A. et al., Meth. in Enzymol., 154, 367 (1987)). Alternatively, a variant of a gene may be totally synthesized.

In addition, when a protein functions as a complex made up of a plurality of subunits, a part or all of the subunits may be modified, so long as the activity of the protein is eventually increased. That is, for example, when the activity of a protein is increased by increasing the expression of a gene, the expression of a part or all of the genes that encode the respective subunits may be enhanced. It is typically preferable to enhance the expression of all of the genes encoding the subunits. Furthermore, the subunits making up the complex may be derived from a single kind of organism or two or more kinds of organisms, so long as the complex has a function of the objective protein. That is, for example, genes of the same organism encoding a plurality of subunits may be introduced into a host, or genes of different organisms encoding a plurality of subunits may be introduced into a host.

Furthermore, the expression of a gene can be increased by improving the transcription efficiency of the gene. In addition, the expression of a gene can also be increased by improving the translation efficiency of the gene. The transcription efficiency of the gene and the translation efficiency of the gene can be improved by, for example, modifying an expression control sequence of the gene. The term “expression control sequence” collectively can refer to sites that affect the expression of a gene. Examples of the expression control sequence can include, for example, a promoter, a Shine-Dalgarno (SD) sequence (also referred to as ribosome-binding site (RBS)), and a spacer region between RBS and the start codon. Expression control sequences can be identified by using a promoter search vector or gene analysis software such as GENETYX. These expression control sequences can be modified by, for example, a method of using a temperature sensitive vector, or the Red driven integration method (WO2005/010175).

The transcription efficiency of a gene can be improved by, for example, replacing the promoter of the gene on a chromosome with a stronger promoter. The term “stronger promoter” can refer to a promoter providing an improved transcription of a gene compared with the inherent wild-type promoter of the gene. Examples of stronger promoters can include, for example, the known high expression promoters such as T7 promoter, trp promoter, lac promoter, thr promoter, tac promoter, trc promoter, tet promoter, araBAD promoter, rpoH promoter, msrA promoter, Pm1 promoter (derived from the genus Bifidobacterium), PR promoter, and PL promoter. Examples of stronger promoters usable in coryneform bacteria can include, for example, the artificially modified P54-6 promoter (Appl. Microbiol. Biotechnol., 53, 674-679 (2000)), pta, aceA, aceB, adh, and amyE promoters inducible in coryneform bacteria with acetic acid, ethanol, pyruvic acid, or the like, cspB, SOD, and tuf (EF-Tu) promoters, which are potent promoters capable of providing a large expression amount in coryneform bacteria (Journal of Biotechnology, 104 (2003) 311-323; Appl. Environ. Microbiol., 2005 December; 71 (12):8587-96), P2 promoter (position 942-1034 of SEQ ID NO: 108), and P3 promoter (SEQ ID NO: 111), as well as lac promoter, tac promoter, and trc promoter. Furthermore, as the stronger promoter, a highly-active type of an existing promoter may also be obtained by using various reporter genes. For example, by making the −35 and −10 regions in a promoter region closer to the consensus sequence, the activity of the promoter can be enhanced (WO00/18935). Examples of a highly active-type promoter can include various tac-like promoters (Katashkina J I et al., Russian Federation Patent Application No. 2006134574). Methods for evaluating the strength of promoters and examples of strong promoters are described in the paper of Goldstein et al. (Prokaryotic Promoters in Biotechnology, Biotechnol. Annu. Rev., 1, 105-128 (1995)), and so forth.

The translation efficiency of a gene can be improved by, for example, replacing the Shine-Dalgarno (SD) sequence, which can also be referred to as ribosome binding site (RBS), for the gene on a chromosome with a stronger SD sequence. The term “stronger SD sequence” can refer to a SD sequence that provides an improved translation of mRNA compared with the inherent wild-type SD sequence of the gene. Examples of stronger SD sequences can include, for example, RBS of the gene 10 derived from phage T7 (Olins P. O. et al, Gene, 1988, 73, 227-235). Furthermore, it is known that substitution, insertion, or deletion of several nucleotides in a spacer region between RBS and the start codon, especially in a sequence immediately upstream of the start codon (5′-UTR), significantly affects the stability and translation efficiency of mRNA, and hence, the translation efficiency of a gene can also be improved by modification.

The translation efficiency of a gene can also be improved by, for example, modifying codons. For example, the translation efficiency of the gene can be improved by replacing a rare codon present in the gene with a more frequently used synonymous codon. That is, the gene to be introduced may be modified, for example, so as to contain optimal codons according to the frequencies of codons observed in the chosen host. Codons can be replaced by, for example, the site-specific mutation method for introducing an objective mutation into an objective site of DNA. Alternatively, a gene fragment in which objective codons are replaced may be entirely synthesized. Frequencies of codons in various organisms are disclosed in the “Codon Usage Database” (kazusa.or.jp/codon; Nakamura, Y. et al, Nucl. Acids Res., 28, 292 (2000)).

Furthermore, the expression of a gene can also be increased by amplifying a regulator that increases the expression of the gene, or deleting or attenuating a regulator that reduces the expression of the gene.

Such methods for increasing the gene expression as described above may be used independently or in an arbitrary combination.

Furthermore, the modification that increases the activity of a protein can also be attained by, for example, enhancing the specific activity of the enzyme. Enhancement of the specific activity can also include desensitization to feedback inhibition. That is, when a protein is subject to feedback inhibition by a metabolite, the activity of the protein can be increased by mutating a gene or protein in the chosen host to be desensitized to the feedback inhibition. The phrase “being desensitized to feedback inhibition” can include complete elimination of the feedback inhibition, and attenuation of the feedback inhibition, unless otherwise stated. Also, the phrase “being desensitized to feedback inhibition”, that is, when feedback inhibition is eliminated or attenuated, can also be referred to as “tolerant to feedback inhibition”. A protein showing an enhanced specific activity can be obtained by, for example, searching various organisms. Furthermore, a highly-active type of an existing protein may also be obtained by introducing a mutation into the existing protein. The mutation to be introduced may be, for example, substitution, deletion, insertion, and/or addition of one or several amino acid residues at one or several positions of the protein. The mutation can be introduced by, for example, such a site-specific mutation method as mentioned above. The mutation may also be introduced by, for example, a mutagenesis treatment. Examples of the mutagenesis treatment can include irradiation of X-ray, irradiation of ultraviolet, and a treatment with a mutation agent such as N-methyl-N′-nitro-N-nitrosoguanidine (MNNG), ethyl methanesulfonate (EMS), and methyl methanesulfonate (MMS). Furthermore, a random mutation may be induced by directly treating DNA in vitro with hydroxylamine. Enhancement of the specific activity may be independently used, or may be used in an arbitrary combination with such methods for enhancing gene expression as mentioned above.

The method for the transformation is not particularly limited, and conventionally known methods can be used. There can be used, for example, a method of treating recipient cells with calcium chloride so as to increase the permeability thereof for DNA, which has been reported for the Escherichia coli K-12 strain (Mandel, M. and Higa, A., J. Mol. Biol., 1970, 53, 159-162), and a method of preparing competent cells from cells which are in the growth phase, followed by transformation with DNA, which has been reported for Bacillus subtilis (Duncan, C. H., Wilson, G. A. and Young, F. E., Gene, 1977, 1:153-167). Alternatively, there can also be used a method of making DNA-recipient cells into protoplasts or spheroplasts, which can easily take up recombinant DNA, followed by introducing a recombinant DNA into the DNA-recipient cells, which is known to be applicable to Bacillus subtilis, actinomycetes, and yeasts (Chang, S. and Choen, S. N., 1979, Mol. Gen. Genet., 168:111-115; Bibb, M. J., Ward, J. M. and Hopwood, O. A., 1978, Nature, 274:398-400; Hinnen, A., Hicks, J. B. and Fink, G. R., 1978, Proc. Natl. Acad. Sci. USA, 75:1929-1933). Furthermore, the electric pulse method reported for coryneform bacteria (Japanese Patent Laid-open (Kokai) No. 2-207791) can also be used.

An increase in the activity of a protein can be confirmed by measuring the activity of the protein.

An increase in the activity of a protein can also be confirmed by confirming an increase in the expression of a gene encoding the protein. An increase in the expression of a gene can be confirmed by confirming an increase in the transcription amount of the gene, or by confirming an increase in the amount of a protein expressed from the gene.

An increase of the transcription amount of a gene can be confirmed by comparing the amount of mRNA transcribed from the gene with that of a non-modified strain, such as a wild-type strain or parent strain. Examples of the method for evaluating the amount of mRNA can include Northern hybridization, RT-PCR, microarray, RNA-seq, and so forth (Sambrook, J., et al., Molecular Cloning: A Laboratory Manual/Third Edition, Cold Spring Harbor Laboratory Press, Cold Spring Harbor (USA), 2001). The amount of mRNA may be increased to, for example, 1.2 times or more, 1.5 times or more, 2 times or more, or 3 times or more of that of a non-modified strain.

An increase in the amount of a protein can be confirmed by Western blotting using antibodies (Sambrook, J., et al., Molecular Cloning: A Laboratory Manual/Third Edition, Cold Spring Harbor Laboratory Press, Cold Spring Harbor (USA), 2001). The amount of the protein, such as the number of molecules of the protein per cell, may be increased to, for example, 1.2 times or more, 1.5 times or more, 2 times or more, or 3 times or more of that of a non-modified strain.

The aforementioned methods for increasing the activity of a protein can be applied to enhancement of the activities of arbitrary proteins such as an objective substance biosynthesis enzyme, phosphopantetheinylation enzyme, and uptake system of a substance, and enhancement of the expression of arbitrary genes such as genes encoding those arbitrary proteins, besides enhancement of the activity of the SAM cycle enzyme.

<1-4> Method for Reducing Activity of Protein

Hereafter, the methods for reducing the activity of a protein will be explained.

The phrase “the activity of a protein is reduced” means that the activity of the protein is reduced as compared with a non-modified strain, that is, as compared with a strain of a non-modified microorganism. Specifically, the phrase “the activity of a protein is reduced” can mean that the activity of the protein per cell is reduced as compared with that of a non-modified strain. The term “non-modified strain” or “strain of a non-modified microorganism” can refer to a control strain that has not been modified so that the activity of an objective protein is reduced. Examples of the non-modified strain can include a wild-type strain and parent strain. Specific examples of the non-modified strain can include the respective type strains of the species of microorganisms. Specific examples of the non-modified strain can also include strains exemplified above in relation to the description of microorganisms. That is, in an embodiment, the activity of a protein may be reduced as compared with a type strain, that is, the type strain of the species to which the microorganism as described herein belongs. In another embodiment, the activity of a protein may also be reduced as compared with the C. glutamicum ATCC 13869 strain. In another embodiment, the activity of a protein may also be reduced as compared with the C. glutamicum ATCC 13032 strain. In another embodiment, the activity of a protein may also be reduced as compared with the E. coli K-12 MG1655 strain. The phrase “the activity of a protein is reduced” can also include when the activity of the protein has completely disappeared. More specifically, the phrase “the activity of a protein is reduced” can mean that the number of molecules of the protein per cell is reduced, and/or the function of each molecule of the protein is reduced, as compared with those of a non-modified strain. That is, the term “activity” in the phrase “the activity of a protein is reduced” is not limited to the catalytic activity of the protein, but can also mean the transcription amount of a gene encoding the protein, that is, the amount of mRNA, or the translation amount of a gene encoding the protein, that is, the amount of the protein. The phrase “the number of molecules of the protein per cell is reduced” can also include when the protein does not exist at all. The phrase “the function of each molecule of the protein is reduced” can also include when the function of each protein molecule has completely disappeared. The degree of the reduction in the activity of a protein is not particularly limited, so long as the activity is reduced as compared with that of a non-modified strain. The activity of a protein may be reduced to, for example, 50% or less, 20% or less, 10% or less, 5% or less, or 0% of that of a non-modified strain.

The modification for reducing the activity of a protein can be attained by, for example, reducing the expression of a gene encoding the protein. The phrase “the expression of a gene is reduced” can mean that the expression of the gene is reduced as compared with a non-modified strain, such as a wild-type strain and parent strain. Specifically, the phrase “the expression of a gene is reduced” can mean that the expression of the gene per cell is reduced as compared with that of a non-modified strain. More specifically, the phrase “the expression of a gene is reduced” can mean that the transcription amount of the gene, that is, the amount of mRNA, is reduced, and/or the translation amount of the gene, that is, the amount of the protein expressed from the gene, is reduced. The phrase “the expression of a gene is reduced” can also include when the gene is not expressed at all. The phrase “the expression of a gene is reduced” can also be referred to as “the expression of a gene is attenuated”. The expression of a gene may be reduced to, for example, 50% or less, 20% or less, 10% or less, 5% or less, or 0% of that of a non-modified strain.

The reduction in gene expression may be due to, for example, a reduction in the transcription efficiency, a reduction in the translation efficiency, or a combination of these. The expression of a gene can be reduced by modifying an expression control sequence of the gene, such as a promoter, a Shine-Dalgarno (SD) sequence (also referred to as ribosome-binding site (RBS)), and a spacer region between RBS and the start codon of the gene. When an expression control sequence is modified, one or more nucleotides, two or more nucleotides, or three or more nucleotides, of the expression control sequence are modified. For example, the transcription efficiency of a gene can be reduced by, for example, replacing the promoter of the gene on a chromosome with a weaker promoter. The term “weaker promoter” can refer to a promoter providing an attenuated transcription of a gene compared with the inherent wild-type promoter of the gene. Examples of weaker promoters can include, for example, inducible promoters. That is, an inducible promoter may function as a weaker promoter under a non-induced condition, such as in the absence of the corresponding inducer. Examples of weaker promoters can also include, for example, P4 and P8 promoters (position 872-969 of SEQ ID NO: 109 and position 901-1046 of SEQ ID NO: 110, respectively). Furthermore, a part of or the entire expression control sequence may be deleted. The expression of a gene can also be reduced by, for example, manipulating a factor responsible for expression control. Examples of the factor responsible for expression control can include low molecules responsible for transcription or translation control, such as inducers, inhibitors, etc., proteins responsible for transcription or translation control, such as transcription factors etc., nucleic acids responsible for transcription or translation control, such as siRNA etc., and so forth. Furthermore, the expression of a gene can also be reduced by, for example, introducing a mutation that reduces the expression of the gene into the coding region of the gene. For example, the expression of a gene can be reduced by replacing a codon in the coding region of the gene with a synonymous codon used less frequently in a host. Furthermore, for example, the gene expression may be reduced due to disruption of a gene as described herein.

The modification for reducing the activity of a protein can also be attained by, for example, disrupting a gene encoding the protein. The phrase “a gene is disrupted” can mean that a gene is modified so that a protein that can normally function is not produced. The phrase “a protein that normally functions is not produced” can include when the protein is not produced at all from the gene, and when the protein of which the function, such as activity or property, per molecule is reduced or eliminated is produced from the gene.

Disruption of a gene can be attained by, for example, deleting the gene on a chromosome. The term “deletion of a gene” can refer to deletion of a partial or the entire region of the coding region of the gene. Furthermore, the whole of a gene including sequences upstream and downstream from the coding region of the gene on a chromosome may be deleted. The region to be deleted may be any region, such as an N-terminal region (i.e. a region encoding an N-terminal region of a protein), an internal region, or a C-terminal region (i.e. a region encoding a C-terminal region of a protein), so long as the activity of the protein can be reduced. Deletion of a longer region will typically more surely inactivate the gene. The region to be deleted may be, for example, a region having a length of 10% or more, 20% or more, 30% or more, 40% or more, 50% or more, 60% or more, 70% or more, 80% or more, 90% or more, or 95% or more of the total length of the coding region of the gene. Furthermore, it is preferred that reading frames of the sequences upstream and downstream from the region to be deleted are not the same. Inconsistency of reading frames may cause a frameshift downstream of the region to be deleted.

Disruption of a gene can also be attained by, for example, introducing a mutation for an amino acid substitution (missense mutation), a stop codon (nonsense mutation), addition or deletion of one or two nucleotide residues (frame shift mutation), or the like into the coding region of the gene on a chromosome (Journal of Biological Chemistry, 272:8611-8617 (1997); Proceedings of the National Academy of Sciences, USA, 95 5511-5515 (1998); Journal of Biological Chemistry, 26 116, 20833-20839 (1991)).

Disruption of a gene can also be attained by, for example, inserting another nucleotide sequence into a coding region of the gene on a chromosome. Site of the insertion may be in any region of the gene, and insertion of a longer nucleotide sequence will typically more surely inactivate the gene. It is preferred that reading frames of the sequences upstream and downstream from the insertion site are not the same. Inconsistency of reading frames may cause a frameshift downstream of the region to be deleted. The other nucleotide sequence is not particularly limited so long as a sequence that reduces or eliminates the activity of the encoded protein is chosen, and examples thereof can include, for example, a marker gene such as antibiotic resistance genes, and a gene useful for production of an objective substance.

Particularly, disruption of a gene may be carried out so that the amino acid sequence of the encoded protein is deleted. In other words, the modification for reducing the activity of a protein can be attained by, for example, deleting the amino acid sequence of the protein, specifically, modifying a gene so as to encode a protein of which the amino acid sequence is deleted. The phrase “deletion of the amino acid sequence of a protein” can refer to deletion of a partial or the entire region of the amino acid sequence of the protein. In addition, the phrase “deletion of the amino acid sequence of a protein” can mean that the original amino acid sequence disappears in the protein, and can also include when the original amino acid sequence is changed to another amino acid sequence. That is, for example, a region that was changed to another amino acid sequence by frameshift may be regarded as a deleted region. When the amino acid sequence of a protein is deleted, the total length of the protein is typically shortened, but there can also be cases where the total length of the protein is not changed or is extended. For example, by deletion of a partial or the entire region of the coding region of a gene, a region encoded by the deleted region can be deleted in the encoded protein. In addition, for example, by introduction of a stop codon into the coding region of a gene, a region encoded by the downstream region of the introduction site can be deleted in the encoded protein. In addition, for example, by frameshift in the coding region of a gene, a region encoded by the frameshift region can be deleted in the encoded protein. The aforementioned descriptions concerning the position and length of the region to be deleted in deletion of a gene can be applied mutatis mutandis to the position and length of the region to be deleted in deletion of the amino acid sequence of a protein.

Such modification of a gene on a chromosome as described above can be attained by, for example, preparing a disruption-type gene modified so that it is unable to produce a protein that normally functions, and transforming a host with a recombinant DNA containing the disruption-type gene to cause homologous recombination between the disruption-type gene and the wild-type gene on a chromosome and thereby substitute the disruption-type gene for the wild-type gene on the chromosome. In this procedure, if a marker gene selected according to the characteristics of the host such as auxotrophy is included in the recombinant DNA, the operation becomes easier. Examples of the disruption-type gene can include a gene of which a partial or the entire region of the coding region is deleted, a gene including a missense mutation, a gene including a nonsense mutation, a gene including a frame shift mutation, and a gene including insertion of a transposon or marker gene. The protein encoded by the disruption-type gene has a conformation different from that of the wild-type protein, even if it is produced, and thus the function thereof is reduced or eliminated. Such gene disruption based on gene substitution utilizing homologous recombination has already been established, and there are methods of using a linear DNA such as a method called “Red driven integration” (Datsenko, K. A, and Wanner, B. L., Proc. Natl. Acad. Sci. USA, 97:6640-6645 (2000)), and a method utilizing the Red driven integration in combination with an excision system derived from λ phage (Cho, E. H., Gumport, R. I., Gardner, J. F., J. Bacteriol., 184:5200-5203 (2002)) (refer to WO2005/010175), a method of using a plasmid having a temperature sensitive replication origin, a method of using a plasmid capable of conjugative transfer, a method of utilizing a suicide vector not having a replication origin that functions in a host (U.S. Pat. No. 6,303,383, Japanese Patent Laid-open (Kokai) No. 05-007491), and so forth.

Modification for reducing activity of a protein can also be attained by, for example, a mutagenesis treatment. Examples of the mutagenesis treatment can include irradiation of X-ray or ultraviolet and treatment with a mutation agent such as N-methyl-N′-nitro-N-nitrosoguanidine (MNNG), ethyl methanesulfonate (EMS), and methyl methanesulfonate (MMS).

Such methods for reducing the activity of a protein as mentioned above may be used independently or in an arbitrary combination.

When a protein functions as a complex made up of a plurality of subunits, a part or all of the subunits may be modified, so long as the activity of the protein is eventually reduced. That is, for example, a part or all of the genes that encode the respective subunits may be disrupted or the like. Furthermore, when there is a plurality of isozymes of a protein, a part or all of the activities of the isozymes may be reduced, so long as the activity of the protein is eventually reduced. That is, for example, a part or all of the genes that encode the respective isozymes may be disrupted or the like.

A reduction in the activity of a protein can be confirmed by measuring the activity of the protein.

A reduction in the activity of a protein can also be confirmed by confirming a reduction in the expression of a gene encoding the protein. A reduction in the expression of a gene can be confirmed by confirming a reduction in the transcription amount of the gene or a reduction in the amount of the protein expressed from the gene.

A reduction in the transcription amount of a gene can be confirmed by comparing the amount of mRNA transcribed from the gene with that of a non-modified strain. Examples of the method for evaluating the amount of mRNA can include Northern hybridization, RT-PCR, microarray, RNA-seq, and so forth (Sambrook, J., et al., Molecular Cloning: A Laboratory Manual/Third Edition, Cold Spring Harbor Laboratory Press, Cold Spring Harbor (USA), 2001). The amount of mRNA may be reduced to, for example, 50% or less, 20% or less, 10% or less, 5% or less, or 0%, of that of a non-modified strain.

A reduction in the amount of a protein can be confirmed by Western blotting using antibodies (Sambrook, J., et al., Molecular Cloning: A Laboratory Manual/Third Edition, Cold Spring Harbor Laboratory Press, Cold Spring Harbor (USA) 2001). The amount of the protein, such as the number of molecules of the protein per cell, may be reduced to, for example, 50% or less, 20% or less, 10% or less, 5% or less, or 0%, of that of a non-modified strain.

Disruption of a gene can be confirmed by determining the nucleotide sequence of a part of or the entire gene, restriction enzyme map, full length, or the like of the gene depending on the means used for the disruption.

The aforementioned methods for reducing the activity of a protein can be applied to reduction in the activities of arbitrary proteins such as a byproduct generation enzyme, and reduction in the expression of arbitrary genes such as genes encoding those arbitrary proteins.

<2> Method for Producing Objective Substance

The method as described herein is a method for producing an objective substance by using the microorganism as described herein.

<2-1> Fermentation Method

An objective substance can be produced by, for example, fermentation of the microorganism as described herein. That is, an embodiment of the method as described herein may be a method for producing an objective substance by fermentation of the microorganism. This embodiment can also be referred to as a “fermentation method”. Also, the step of producing an objective substance by fermentation of the microorganism can also be referred to as a “fermentation step”.

The fermentation step can be performed by cultivating the microorganism as described herein. Specifically, in the fermentation method, an objective substance can be produced from a carbon source. That is, the fermentation step may be, for example, a step of cultivating the microorganism in a culture medium, such as a culture medium containing a carbon source, to produce and accumulate the objective substance in the culture medium. That is, the fermentation method may be a method for producing an objective substance that comprises the step of cultivating the microorganism in a culture medium, such as a culture medium containing a carbon source, to produce and accumulate the objective substance in the culture medium. Also, in other words, the fermentation step may be, for example, a step of producing the objective substance from a carbon source by using the microorganism.

The culture medium to be used is not particularly limited, so long as the microorganism can proliferate in it and produce an objective substance. As the culture medium, for example, a typical culture medium used for the culture of microorganisms such as bacteria and yeast can be used. The culture medium may contain carbon source, nitrogen source, phosphate source, and sulfur source, as well as other medium components such as various organic components and inorganic components as required. The types and concentrations of the medium components can be appropriately determined according to various conditions such as the type of the chosen microorganism.

The carbon source is not particularly limited, so long as the microorganism can utilize it and produce an objective substance. Specific examples of the carbon source can include, for example, saccharides such as glucose, fructose, sucrose, lactose, galactose, xylose, arabinose, blackstrap molasses, hydrolysates of starches, and hydrolysates of biomass; organic acids such as acetic acid, citric acid, succinic acid, and gluconic acid; alcohols such as ethanol, glycerol, and crude glycerol; and fatty acids. As the carbon source, in particular, plant-derived materials can be used. Examples of the plant can include, for example, corn, rice, wheat, soybean, sugarcane, beet, and cotton. Examples of the plant-derived materials can include, for example, organs such as root, stem, trunk, branch, leaf, flower, and seed, plant bodies including them, and decomposition products of these plant organs. The forms of the plant-derived materials at the time of use thereof are not particularly limited, and they can be used in any form such as unprocessed product, juice, ground product, and purified product. Pentoses such as xylose, hexoses such as glucose, or mixtures of them can be obtained from, for example, plant biomass, and used. Specifically, these saccharides can be obtained by subjecting a plant biomass to such a treatment as steam treatment, hydrolysis with concentrated acid, hydrolysis with diluted acid, hydrolysis with an enzyme such as cellulase, and alkaline treatment. Since hemicellulose is generally more easily hydrolyzed compared with cellulose, hemicellulose in a plant biomass may be hydrolyzed beforehand to liberate pentoses, and then cellulose may be hydrolyzed to generate hexoses. Furthermore, xylose may be supplied by conversion from hexoses by, for example, imparting a pathway for converting hexose such as glucose to xylose to the microorganism. As the carbon source, one kind of carbon source may be used, or two or more kinds of carbon sources may be used in combination.

The concentration of the carbon source in the culture medium is not particularly limited, so long as the microorganism can proliferate and produce an objective substance. The concentration of the carbon source in the culture medium may be as high as possible and within such a range that production of the objective substance is not inhibited. The initial concentration of the carbon source in the culture medium may be, for example, 5 to 30% (w/v), or 10 to 20% (w/v). Furthermore, the carbon source may be added to the culture medium as required. For example, the carbon source may be added to the culture medium in proportion to decrease or depletion of the carbon source accompanying progress of the fermentation. While the carbon source may be temporarily depleted so long as an objective substance can be eventually produced, it may be preferable to perform the culture so that the carbon source is not depleted or the carbon source does not continue to be depleted.

Specific examples of the nitrogen source can include, for example, ammonium salts such as ammonium sulfate, ammonium chloride, and ammonium phosphate, organic nitrogen sources such as peptone, yeast extract, meat extract, and soybean protein decomposition products, ammonia, and urea. Ammonia gas and aqueous ammonia used for pH adjustment may also be used as a nitrogen source. As the nitrogen source, one nitrogen source may be used, or two or more nitrogen sources may be used in combination.

Specific examples of the phosphate source can include, for example, phosphate salts such as potassium dihydrogenphosphate and dipotassium hydrogenphosphate, and phosphoric acid polymers such as pyrophosphoric acid. As the phosphate source, one phosphate source may be used, or two or more phosphate sources may be used in combination.

Specific examples of the sulfur source can include, for example, inorganic sulfur compounds such as sulfates, thiosulfates, and sulfites, and sulfur-containing amino acids such as cysteine, cystine, and glutathione. As the sulfur source, one sulfur source may be used, or two or more sulfur sources may be used in combination.

Specific examples of other various organic and inorganic components can include, for example, inorganic salts such as sodium chloride and potassium chloride; trace metals such as iron, manganese, magnesium, and calcium; vitamins such as vitamin B1, vitamin B2, vitamin B6, nicotinic acid, nicotinamide, and vitamin B12; amino acids; nucleic acids; and organic components containing these such as peptone, casamino acid, yeast extract, and soybean protein decomposition product. As the other various organic and inorganic components, one kind of component may be used, or two or more kinds of components may be used in combination.

Furthermore, when an auxotrophic mutant strain that requires a nutrient such as amino acids for growth thereof is used, the culture medium may preferably contain such a required nutrient. Furthermore, the culture medium may contain a component used for production of an objective substance. Specific examples of such a component can include, for example, methyl group donors such as SAM and precursors thereof such as methionine.

Culture conditions are not particularly limited, so long as the microorganism can proliferate, and an objective substance is produced. The culture can be performed with, for example, typical conditions used for culture of microorganisms such as bacteria and yeast. The culture conditions may be appropriately determined according to various conditions such as the type of the chosen microorganism.

The culture can be performed by using a liquid medium. At the time of the culture, for example, the microorganism cultured on a solid medium such as agar medium may be directly inoculated into a liquid medium, or the microorganism cultured in a liquid medium as seed culture may be inoculated into a liquid medium for main culture. That is, the culture may be performed separately as seed culture and main culture. In such a case, the culture conditions of the seed culture and the main culture may or may not be the same. It is sufficient that an objective substance is produced at least during the main culture. The amount of the microorganism present in the culture medium at the time of the start of the culture is not particularly limited. For example, a seed culture broth showing an OD660 of 4 to 100 may be inoculated to a culture medium for main culture in an amount of 0.1 to 100 mass %, or 1 to 50 mass %, at the time of the start of the culture.

The culture can be performed as batch culture, fed-batch culture, continuous culture, or a combination of these. The culture medium used at the start of the culture can also be referred to as a “starting medium”. The culture medium added to the culture system (e.g. fermentation tank) in the fed-batch culture or the continuous culture can also be referred to as a “feed medium”. To add a feed medium to the culture system in the fed-batch culture or the continuous culture can also be referred to as “feed”. Furthermore, when the culture is performed separately as seed culture and main culture, the culture schemes of the seed culture and the main culture may or may not be the same. For example, both the seed culture and the main culture may be performed as batch culture. Alternatively, for example, the seed culture may be performed as batch culture, and the main culture may be performed as fed-batch culture or continuous culture.

The various components, such as the carbon source, may be present in the starting medium, feed medium, or both. That is, the various components, such as the carbon source, may be added to the culture medium independently or in an arbitrary combination during the culture. These components may be added once or a plurality of times, or may be continuously added. The types of the components present in the starting medium may or may not be the same as the types of the components present in the feed medium. Furthermore, the concentrations of the components present in the starting medium may or may not be the same as the concentrations of the components present in the feed medium. Furthermore, two or more kinds of feed media containing components of different types and/or different concentrations may be used. For example, when feeding is intermittently performed two or more times, the types and/or concentrations of components present in the feed medium may or may not be the same for each feeding.

The culture can be performed, for example, under an aerobic condition. The term “aerobic condition” can refer to a condition where the dissolved oxygen concentration in the culture medium is 0.33 ppm or higher, or 1.5 ppm or higher. The oxygen concentration can be controlled to be, for example, 1 to 50%, or about 5%, of the saturated oxygen concentration. The culture can be performed, for example, with aeration or shaking. The pH of the culture medium may be, for example, 3 to 10, or 4.0 to 9.5. The pH of the culture medium can be adjusted during the culture as required. The pH of the culture medium can be adjusted by using various alkaline and acidic substances such as ammonia gas, aqueous ammonia, sodium carbonate, sodium bicarbonate, potassium carbonate, potassium bicarbonate, magnesium carbonate, sodium hydroxide, calcium hydroxide, and magnesium hydroxide. The culture temperature may be, for example, 20 to 45° C., or 25 to 37° C. The culture time may be, for example, 10 to 120 hours. The culture may be continued, for example, until the carbon source present in the culture medium is consumed, or until the activity of the microorganism is lost.

By cultivating the microorganism under such conditions as described above, an objective substance is accumulated in the culture medium.

Production of an objective substance can be confirmed by known methods used for detection or identification of compounds. Examples of such methods can include, for example, HPLC, UPLC, LC/MS, GC/MS, and NMR. These methods may be independently used, or may be used in an appropriate combination. These methods can also be used for determining the concentrations of various components present in the culture medium.

The produced objective substance can be appropriately collected. That is, the fermentation method may further comprise a step of collecting the objective substance. This step can also be referred to as a “collection step”. The collection step may be a step of collecting the objective substance from the culture broth, specifically from the culture medium. The objective substance can be collected by known methods used for separation and purification of compounds. Examples of such methods can include, for example, ion-exchange resin method, membrane treatment, precipitation, extraction, distillation, and crystallization. The objective substance can be collected specifically by extraction with an organic solvent such as ethyl acetate or by steam distillation. These methods may be independently used, or may be used in an appropriate combination.

Furthermore, when an objective substance precipitates in the culture medium, it can be collected by, for example, centrifugation or filtration. The objective substance precipitated in the culture medium and the objective substance dissolved in the culture medium may be isolated together after the objective substance dissolved in the culture medium is crystallized.

The collected objective substance may contain, for example, other component(s) such as microbial cells, medium components, moisture, and by-product metabolites of the microorganism, in addition to the objective substance. Purity of the collected objective substance may be, for example, 30% (w/w) or higher, 50% (w/w) or higher, 70% (w/w) or higher, 80% (w/w) or higher, 90% (w/w) or higher, or 95% (w/w) or higher.

<2-2> Bioconversion Method

An objective substance can also be produced by, for example, bioconversion using the microorganism as described herein. That is, another embodiment of the method as described herein may be a method for producing an objective substance by bioconversion using the microorganism. This embodiment can also be referred to as a “bioconversion method”. Also, the step of producing an objective substance by bioconversion using the microorganism can also be referred to as a “bioconversion step”.

Specifically, in the bioconversion method, an objective substance can be produced from a precursor of the objective substance. More specifically, in the bioconversion method, an objective substance can be produced by converting a precursor of the objective substance into the objective substance by using the microorganism. That is, the bioconversion step may be a step of converting a precursor of an objective substance into the objective substance by using the microorganism.

A precursor of an objective substance can also be referred to simply as a “precursor”. Examples of the precursor can include substances of which conversion into an object substance requires SAM. Specific examples of the precursor can include intermediates of the biosynthesis pathway of an object substance, such as those recited in relation to the descriptions of the objective substance biosynthesis enzymes, provided that conversion of the intermediates into the object substance requires SAM. More specific examples of the precursor can include, for example, protocatechuic acid, protocatechualdehyde, L-tryptophan, L-histidine, L-phenylalanine, L-tyrosine, L-arginine, L-ornithine, and glycine. Protocatechuic acid may be used as a precursor for producing, for example, vanillin, vanillic acid, or guaiacol. Protocatechualdehyde may be used as a precursor for producing, for example, vanillin. L-tryptophan may be used as a precursor for producing, for example, melatonin. L-histidine may be used as a precursor for producing, for example, ergothioneine. L-phenylalanine and L-tyrosine each may be used as a precursor for producing, for example, ferulic acid, 4-vinylguaiacol, or 4-ethylguaiacol. L-arginine and L-ornithine each may be used as a precursor for producing, for example, a polyamine. L-arginine and glycine each may be used as a precursor for producing, for example, creatine. As the precursor, one kind of precursor may be used, or two or more kinds of precursors may be used in combination. In cases where the precursor is a compound that can form a salt, the precursor may be used as a free compound, a salt thereof, or a mixture thereof. That is, the term “precursor” can refer to a precursor in a free form, a salt thereof, or a mixture thereof, unless otherwise stated. Examples of the salt can include, for example, sulfate salt, hydrochloride salt, carbonate salt, ammonium salt, sodium salt, and potassium salt. As the salt of the precursor, one kind of salt may be employed, or two or more kinds of salts may be employed in combination.

As the precursor, a commercial product may be used, or one appropriately prepared and obtained may be used. That is, the bioconversion method may further comprise a step of producing a precursor. The method for producing a precursor is not particularly limited, and for example, known methods can be used. A precursor can be produced by, for example, a chemical synthesis method, enzymatic method, bioconversion method, fermentation method, extraction method, or a combination of these. That is, for example, a precursor of an objective substance can be produced from a further precursor thereof using an enzyme that catalyzes the conversion of such a further precursor into the precursor of an objective substance, which enzyme can also be referred to as a “precursor biosynthesis enzyme”. Furthermore, for example, a precursor of an objective substance can be produced from a carbon source or such a further precursor by using a microorganism having a precursor-producing ability. The phrase “microorganism having a precursor-producing ability” can refer to a microorganism that is able to generate a precursor of an objective substance from a carbon source or a further precursor thereof. For example, examples of the method for producing protocatechuic acid according to an enzymatic method or bioconversion method can include the method of converting para-cresol into protocatechuic acid using Pseudomonas putida KS-0180 (Japanese Patent Laid-open (Kokai) No. 7-75589), the method of converting para-hydroxybenzoic acid into protocatechuic acid using an NADH-dependent para-hydroxybenzoic acid hydroxylase (Japanese Patent Laid-open (Kokai) No. 5-244941), the method of producing protocatechuic acid by cultivating a transformant harboring a gene that is involved in the reaction of generating protocatechuic acid from terephthalic acid in a culture medium containing terephthalic acid (Japanese Patent Laid-open (Kokai) No. 2007-104942), and the method of producing protocatechuic acid from a precursor thereof by using a microorganism having protocatechuic acid-producing ability and having a reduced activity of protocatechuic acid 5-oxidase or being deficient in that activity (Japanese Patent Laid-open (Kokai) No. 2010-207094). Furthermore, examples of the method for producing protocatechuic acid by fermentation can include the method of producing protocatechuic acid by using a bacterium of the genus Brevibacterium and acetic acid as a carbon source (Japanese Patent Laid-open (Kokai) No. 50-89592), the method of producing protocatechuic acid by using a bacterium of the genus Escherichia or Klebsiella introduced with a gene encoding 3-dihydroshikimate dehydrogenase and glucose as a carbon source (U.S. Pat. No. 5,272,073). Furthermore, protocatechualdehyde can be produced by using protocatechuic acid as a precursor according to an enzymatic method using ACAR or a bioconversion method using a microorganism having ACAR. The produced precursor can be used for the bioconversion method as it is, or after being subjected to an appropriate treatment such as concentration, dilution, drying, dissolution, fractionation, extraction, and purification, as required. That is, as the precursor, for example, a purified product purified to a desired extent may be used, or a material containing a precursor may be used. The material containing a precursor is not particularly limited so long as the microorganism can use the precursor. Specific examples of the material containing a precursor can include a culture broth obtained by cultivating a microorganism having a precursor-producing ability, a culture supernatant separated from the culture broth, and processed products thereof such as concentrated products, such as concentrated liquid, thereof and dried products thereof.

In an embodiment, the bioconversion step can be performed by, for example, cultivating the microorganism as described herein. This embodiment can also be referred to as a “first embodiment of the bioconversion method”. That is, the bioconversion step may be, for example, a step of cultivating the microorganism in a culture medium containing a precursor of an objective substance to convert the precursor into the objective substance. The bioconversion step may be, specifically, a step of cultivating the microorganism in a culture medium containing a precursor of an objective substance to produce and accumulate the objective substance in the culture medium.

The culture medium to be used is not particularly limited, so long as the culture medium contains a precursor of an objective substance, and the microorganism can proliferate in it and produce the objective substance. Culture conditions are not particularly limited, so long as the microorganism can proliferate, and an objective substance is produced. The descriptions concerning the culture mentioned for the fermentation method, such as those concerning the culture medium and culture conditions, can be applied mutatis mutandis to the culture in the first embodiment of the bioconversion method, except that the culture medium contains the precursor in the first embodiment.

The precursor may be present in the culture medium over the whole period of the culture, or may be present in the culture medium during only a partial period of the culture. That is, the phrase “cultivating a microorganism in a culture medium containing a precursor” does not necessarily mean that the precursor is present in the culture medium over the whole period of the culture. For example, the precursor may or may not be present in the culture medium from the start of the culture. When the precursor is not present in the culture medium at the time of the start of the culture, the precursor is added to the culture medium after the start of the culture. Timing of the addition can be appropriately determined according to various conditions such as the length of the culture period. For example, after the microorganism sufficiently grows, the precursor may be added to the culture medium. Furthermore, in any case, the precursor may be added to the culture medium as required. For example, the precursor may be added to the culture medium in proportion to decrease or depletion of the precursor accompanying generation of an objective substance. Methods for adding the precursor to the culture medium are not particularly limited. For example, the precursor can be added to the culture medium by feeding a feed medium containing the precursor to the culture medium. Furthermore, for example, the microorganism as described herein and a microorganism having a precursor-producing ability can be co-cultured to allow the microorganism having a precursor-producing ability to produce the precursor in the culture medium, and thereby add the precursor to the culture medium. For the phrase “a component is added to a culture medium”, the indicated “a component” may include a component that is generated or regenerated in the culture medium. These methods of addition may be independently used, or may be used in an appropriate combination. The concentration of the precursor in the culture medium is not particularly limited so long as the microorganism can use the precursor as a raw material of an objective substance. The concentration of the precursor in the culture medium, for example, may be 0.1 g/L or higher, 1 g/L or higher, 2 g/L or higher, 5 g/L or higher, 10 g/L or higher, or 15 g/L or higher, or may be 200 g/L or lower, 100 g/L or lower, 50 g/L or lower, or 20 g/L or lower, or may be within a range defined with a combination thereof, in terms of the weight of the free compound. The precursor may or may not be present in the culture medium at a concentration within the range exemplified above over the whole period of the culture. For example, the precursor may be present in the culture medium at a concentration within the range exemplified above at the time of the start of the culture, or it may be added to the culture medium so that a concentration within the range exemplified above is attained after the start of the culture. When the culture is performed separately as a seed culture and main culture, it is sufficient that an objective substance is produced at least during the main culture. Hence, it is sufficient that the precursor is present in the culture medium at least during the main culture, that is, over the whole period of the main culture or during a partial period of the main culture, and that is, the precursor may or may not be present in the culture medium during the seed culture. In such cases, terms regarding the culture, such as “culture period (period of culture)” and “start of culture”, can be read as those regarding the main culture.

In another embodiment, the bioconversion step can also be performed by, for example, using cells of the microorganism as described herein. This embodiment can also be referred to as a “second embodiment of the bioconversion method”. That is, the bioconversion step may be, for example, a step of converting a precursor of an objective substance in a reaction mixture into the objective substance by using cells of the microorganism. The bioconversion step may be, specifically, a step of allowing cells of the microorganism to act on a precursor of an objective substance in a reaction mixture to generate and accumulate the objective substance in the reaction mixture. The bioconversion step performed by using such cells can also be referred to as a “conversion reaction”.

Cells of the microorganism can be obtained by cultivating the microorganism. The culture method for obtaining the cells is not particularly limited so long as the microorganism can proliferate. At the time of the culture for obtaining the cells, the precursor may or may not be present in the culture medium. Also, at the time of the culture for obtaining the cells, an objective substance may or may not be produced in the culture medium. The descriptions concerning the culture mentioned for the fermentation method, such as those concerning the culture medium and culture conditions, can be applied mutatis mutandis to the culture for obtaining the cells used for the second embodiment of the bioconversion method.

The cells may be used for the conversion reaction while being present in the culture broth (specifically, culture medium), or after being collected from the culture broth (specifically, culture medium). The cells may also be used for the conversion reaction after being subjected to a treatment as required. That is, examples of the cells can include a culture broth containing the cells, the cells collected from the culture broth, and a processed product thereof. In other words, examples of the cells can include cells present in a culture broth of the microorganism, cells collected from the culture broth, or cells present in a processed product thereof. Examples of the processed product can include products obtained by subjecting the cells to a treatment. Specific examples of the processed product can include products obtained by subjecting a culture broth containing the cells to a treatment, or subjecting the cells collected from the culture broth to a treatment. Cells in these forms may be independently used, or may be used in an appropriate combination.

The method for collecting the cells from the culture medium is not particularly limited, and for example, known methods can be used. Examples of such methods can include, for example, spontaneous precipitation, centrifugation, and filtration. A flocculant may also be used. These methods may be independently used, or may be used in an appropriate combination. The collected cells can be washed as required by using an appropriate medium. The collected cells can be re-suspended as required by using an appropriate medium. Examples of the medium usable for washing or suspending the cells can include, for example, aqueous media (aqueous solvents) such as water and aqueous buffer.

Examples of the treatment of the cells can include, for example, dilution, condensation, immobilization on a carrier such as acrylamide and carrageenan, freezing and thawing treatment, and treatment for increasing permeability of cell membranes. Permeability of cell membranes can be increased by, for example, using a surfactant or organic solvent. These treatments may be independently used, or may be used in an appropriate combination.

The cells used for the conversion reaction are not particularly limited so long as the cells have the objective substance-producing ability. It is preferred that the cells maintain their metabolic activities. The phrase “the cells maintain their metabolic activities” can mean that the cells have an ability to utilize a carbon source to generate or regenerate a substance required for producing an objective substance. Examples of such a substance can include, for example, ATP, electron donors such as NADH and NADPH, and methyl group donors such as SAM. The cells may or may not have proliferation ability.

The conversion reaction can be carried out in an appropriate reaction mixture. Specifically, the conversion reaction can be carried out by allowing the cells and the precursor to coexist in an appropriate reaction mixture. The conversion reaction may be carried out by the batch method or may be carried out by the column method. In the case of the batch method, the conversion reaction can be carried out by, for example, mixing the cells of the microorganism and the precursor in a reaction mixture present in a reaction vessel. The conversion reaction may be carried out statically, or may be carried out with stirring or shaking the reaction mixture. In the case of the column method, the conversion reaction can be carried out by, for example, passing a reaction mixture containing the precursor through a column filled with immobilized cells. Examples of the reaction mixture can include those based on an aqueous medium (aqueous solvent) such as water and aqueous buffer.

The reaction mixture may contain components other than the precursor as required, in addition to the precursor. Examples of the components other than the precursor can include ATP, electron donors such as NADH and NADPH, methyl group donors such as SAM, metal ions, buffering agents, surfactants, organic solvents, carbon sources, phosphate sources, and other various medium components. That is, for example, a culture medium containing the precursor may also be used as a reaction mixture. That is, the descriptions concerning the culture medium mentioned for the first embodiment of the bioconversion method may also be applied mutatis mutandis to the reaction mixture in the second embodiment of the bioconversion method. The types and concentrations of the components present in the reaction mixture may be determined according to various conditions such as the type of the precursor to be used and the form of the cells to be used.

Conditions of the conversion reaction, such as dissolved oxygen concentration, pH of the reaction mixture, reaction temperature, reaction time, concentrations of various components, etc., are not particularly limited so long as an objective substance is generated. The conversion reaction can be performed with, for example, typical conditions used for substance conversion using microbial cells such as resting cells. The conditions of the conversion reaction may be determined according to various conditions such as the type of chosen microorganism. The conversion reaction can be performed, for example, under an aerobic condition. The term “aerobic condition” can refer to a condition where the dissolved oxygen concentration in the reaction mixture is 0.33 ppm or higher, or 1.5 ppm or higher. The oxygen concentration can be controlled to be, for example, 1 to 50%, or about 5%, of the saturated oxygen concentration. The pH of the reaction mixture may be, for example, typically 6.0 to 10.0, or 6.5 to 9.0. The reaction temperature may be, for example, typically 15 to 50° C., 15 to 45° C., or 20 to 40° C. The reaction time may be, for example, 5 minutes to 200 hours. In the case of the column method, the loading rate of the reaction mixture may be, for example, such a rate that the reaction time falls within the range of the reaction time exemplified above. Furthermore, the conversion reaction can also be performed with, for example, a culture condition, such as typical conditions used for culture of microorganisms such as bacteria and yeast. During the conversion reaction, the cells may or may not proliferate. That is, the descriptions concerning the culture conditions for the first embodiment of the bioconversion method may also be applied mutatis mutandis to the conditions of the conversion reaction in the second embodiment of the bioconversion method, except that the cells may or may not proliferate in the second embodiment. In such a case, the culture conditions for obtaining the cells and the conditions of the conversion reaction may be the same or different. The concentration of the precursor in the reaction mixture, for example, may be 0.1 g/L or higher, 1 g/L or higher, 2 g/L or higher, 5 g/L or higher, 10 g/L or higher, or 15 g/L or higher, or may be 200 g/L or lower, 100 g/L or lower, 50 g/L or lower, or 20 g/L or lower, or may be within a range defined with a combination thereof, in terms of the weight of the free compound. The density of the cells in the reaction mixture, for example, may be 1 or higher, or may be 300 or lower, or may be within a range defined with a combination thereof, in terms of the optical density (OD) at 600 nm.

During the conversion reaction, the cells, the precursor, and the other components may be added to the reaction mixture independently or in any arbitrary combination thereof. For example, the precursor may be added to the reaction mixture in proportion to decrease or depletion of the precursor accompanying generation of an objective substance. These components may be added once or a plurality of times, or may be continuously added.

Methods for adding the various components such as the precursor to the reaction mixture are not particularly limited. These components each can be added to the reaction mixture by, for example, directly adding them to the reaction mixture. Furthermore, for example, the microorganism as described herein and a microorganism having a precursor-producing ability can be co-cultured to allow the microorganism having a precursor-producing ability to produce the precursor in the reaction mixture, and thereby add the precursor to the reaction mixture. Furthermore, for example, components such as ATP, electron donors, and methyl group donors each may be generated or regenerated in the reaction mixture, may be generated or regenerated in the cells of the microorganism, or may be generated or regenerated by a coupling reaction between different cells. For example, when cells of the microorganism maintain the metabolic activities thereof, they can generate or regenerate components such as ATP, electron donors, and methyl group donors within them by using a carbon source. For example, specifically, the microorganism may have an enhanced ability for generating or regenerating SAM, and the generated or regenerated SAM by it may be used for the conversion reaction. The generation or regeneration of SAM may further be enhanced in combination with any other method for generating or regenerating SAM. In addition, examples of the method for generating or regenerating ATP can include, for example, the method of supplying ATP from a carbon source by using a Corynebacterium bacterium (Hori, H. et al., Appl. Microbiol. Biotechnol., 48(6):693-698 (1997)), the method of regenerating ATP by using yeast cells and glucose (Yamamoto, S et al., Biosci. Biotechnol. Biochem., 69(4):784-789 (2005)), the method of regenerating ATP using phosphoenolpyruvic acid and pyruvate kinase (C. Aug'e and Ch. Gautheron, Tetrahedron Lett., 29:789-790 (1988)), and the method of regenerating ATP by using polyphosphoric acid and polyphosphate kinase (Murata, K. et al., Agric. Biol. Chem., 52(6):1471-1477 (1988)). For the phrase “a component is added to a reaction mixture”, the indicated “a component” may include a component that is generated or regenerated in the reaction mixture.

Furthermore, the reaction conditions may be constant from the start to the end of the conversion reaction, or they may vary during the conversion reaction. The phrase “the reaction conditions vary during the conversion reaction” can include not only when the reaction conditions are temporally changed, but also when the reaction conditions are spatially changed. The phrase “the reaction conditions are spatially changed” can mean that, for example, when the conversion reaction is performed by the column method, the reaction conditions such as reaction temperature and cell density differ depending on position in the flow.

A culture broth (specifically, culture medium) or reaction mixture containing an objective substance is obtained by carrying out the bioconversion step as described above. Confirmation of the production of the objective substance and collection of the objective substance can be carried out in the same manners as those for the fermentation method described above. That is, the bioconversion method may further comprise the collection step, such as a step of collecting the objective substance from the culture broth (specifically, culture medium) or reaction mixture. The collected objective substance may contain, for example, other component(s) such as microbial cells, medium components, reaction mixture components, moisture, and by-product metabolites of the microorganism, in addition to the objective substance. Purity of the collected objective substance may be, for example, 30% (w/w) or higher, 50% (w/w) or higher, 70% (w/w) or higher, 80% (w/w) or higher, 90% (w/w) or higher, or 95% (w/w) or higher.

<2-3> Method for Producing Vanillin and Other Objective Substances

When an objective substance is produced by using the microorganism as described herein, that is, by the fermentation method or bioconversion method, the thus-produced objective substance can further be converted to another objective substance. The present invention thus provides a method for producing a second objective substance, the method comprising steps of producing a first objective substance by using the microorganism, that is, by the fermentation method or bioconversion method, and converting the thus-produced first objective substance to the second objective substance.

For example, when vanillic acid is produced by using the microorganism as described herein, that is, by the fermentation method or bioconversion method, the thus-produced vanillic acid can further be converted to vanillin. The present invention thus provides a method for producing vanillin, the method comprising steps of producing vanillic acid by using the microorganism, that is, by the fermentation method or bioconversion method, and converting the thus-produced vanillic acid into vanillin. This method can also be referred to as a “vanillin production method”.

Vanillic acid produced by using the microorganism can be used for the conversion into vanillin as it is, or after being subjected to an appropriate treatment such as concentration, dilution, drying, dissolution, fractionation, extraction, and purification, as required. That is, as vanillic acid, for example, a purified product purified to a desired extent may be used, or a material containing vanillic acid may be used. The material containing vanillic acid is not particularly limited so long as a component that catalyzes the conversion, such as a microorganism and an enzyme, can use vanillic acid. Specific examples of the material containing vanillic acid can include a culture broth or reaction mixture containing vanillic acid, a supernatant separated from the culture broth or reaction mixture, and processed products thereof such as concentrated products (such as concentrated liquid) thereof and dried products thereof.

The method for converting vanillic acid into vanillin is not particularly limited.

Vanillic acid can be converted into vanillin by, for example, a bioconversion method using a microorganism having ACAR. The microorganism having ACAR may or may not be modified so that the activity of an SAM cycle enzyme is increased. The descriptions concerning the microorganism as described herein can be applied mutatis mutandis to the microorganism having ACAR, except that the microorganism having ACAR has ACAR and may or may not be modified so that the activity of an SAM cycle enzyme is increased. The microorganism having ACAR may be modified so that the activity or activities of one or more of ACAR, PPT, and the vanillic acid uptake system is/are enhanced. In addition, the descriptions concerning the bioconversion method for producing an objective substance using the microorganism can be applied mutatis mutandis to the bioconversion method for converting vanillic acid into vanillin using a microorganism having ACAR.

Vanillic acid can also be converted into vanillin by, for example, an enzymatic method using ACAR.

ACAR can be produced by allowing a host having an ACAR gene to express the ACAR gene. ACAR can also be produced with a cell-free protein expression system.

A host having an ACAR gene can also be referred to as a “host having ACAR”. The host having an ACAR gene may be a host inherently having the ACAR gene or may be a host modified to have the ACAR gene. Examples of the host inherently having an ACAR gene can include organisms from which ACARs exemplified above are derived. Examples of the host modified to have an ACAR gene can include hosts into which the ACAR gene has been introduced. Also, a host inherently having an ACAR gene may be modified so that the expression of ACAR is increased. The host to be used for expression of ACAR is not particularly limited, so long as the host can express an ACAR that can function. Examples of the host can include, for example, microorganisms such as bacteria and yeast (fungi), plant cells, insect cells, and animal cells.

An ACAR gene can be expressed by cultivating a host having the ACAR gene. The culture method is not particularly limited so long as the host having the ACAR gene can proliferate and express ACAR. The descriptions concerning the culture for the fermentation method can be applied mutatis mutandis to the culture of the host having the ACAR gene. As necessarily, expression of the ACAR gene can be induced. As a result of cultivation, a culture broth containing ACAR can be obtained. ACAR can be accumulated in cells of the host and/or the culture medium.

ACAR present in the cells of the host, the culture medium, or the like may be used as it is for the enzymatic reaction, or ACAR purified therefrom may be used for the enzymatic reaction. Purification can be performed to a desired extent. That is, as ACAR, purified ACAR may be used, or a fraction containing ACAR may be used. Such a fraction is not particularly limited, so long as ACAR present therein can act on vanillic acid. Examples of such a fraction can include, a culture broth of a host having an ACAR gene, that is a host having ACAR; cells collected from the culture broth; processed products of the cells such as cell disruptant, cell lysate, cell extract, and immobilized cells such as those immobilized with acrylamide, carrageenan, or the like; a culture supernatant collected from the culture broth; partially purified products thereof, that is, a crude product; and combinations thereof. These fractions may be used independently, or in combination with purified ACAR.

The enzymatic reaction can be performed by allowing ACAR to act on vanillic acid. Conditions of the enzymatic reaction are not particularly limited so long as vanillin is generated. The enzymatic reaction can be performed with, for example, typical conditions used for substance conversion using an enzyme or microbial cells such as resting cells. For example, the descriptions concerning the conversion reaction in the second embodiment of the bioconversion method may also be applied mutatis mutandis to the enzymatic reaction in the vanillin production method.

A reaction mixture containing vanillin is obtained by carrying out the conversion as described above. Confirmation of the production of vanillin and collection of vanillin can be carried out in the same manners as those for the fermentation method described above. That is, the vanillin production method may further comprise a step of collecting vanillin from the reaction mixture. The collected vanillin may contain, for example, other component(s) such as microbial cells, medium components, reaction mixture components, ACAR, moisture, and by-product metabolites of the microorganism, in addition to vanillin. Purity of the collected vanillin may be, for example, 30% (w/w) or higher, 50% (w/w) or higher, 70% (w/w) or higher, 80% (w/w) or higher, 90% (w/w) or higher, or 95% (w/w) or higher.

Vanillic acid can also be converted to guaiacol by, for example, a bioconversion method using a microorganism having VDC or an enzymatic method using VDC. Ferulic acid can be converted to 4-vinylguaiacol by, for example, a bioconversion method using a microorganism having FDC or an enzymatic method using FDC. 4-vinylguaiacol can be converted to 4-ethylguaiacol by, for example, a bioconversion method using a microorganism having VPR or an enzymatic method using VPR. Ferulic acid can also be converted to 4-ethylguaiacol by a combination of these methods. Specifically, ferulic acid can be converted to 4-ethylguaiacol by, for example, using FDC or a microorganism having FDC in combination with VPR or a microorganism having VPR simultaneously or sequentially, or using a microorganism having both FDC and VPR. The aforementioned descriptions concerning the vanillin production method can be applied mutatis mutandis to methods for producing other objective substances.

EXAMPLES

Hereafter, the present invention will be more specifically explained with reference to the following non-limiting examples.

Example 1: Vanillic Acid Production by C. glutamicum Strain Having Enhanced Expression of metK Gene Encoding Methionine Adenosyltransferase

In this example, a strain having enhanced expression of the NCgl1541 gene (metK) encoding methionine adenosyltransferase was constructed from the Corynebacterium glutamicum 2256 strain (ATCC 13869) as a parent strain, and vanillic acid production was performed with the constructed strain.

<1> Construction of Strain Deficient in Vanillate Demethylase Genes (FKS0165 Strain)

It has been reported that, in coryneform bacteria, vanillin is metabolized in the order of vanillin→vanillic acid→protocatechuic acid, and utilized (Current Microbiology, 2005, Vol. 51, pp. 59-65). The conversion reaction from vanillic acid to protocatechuic acid is catalyzed by vanillate demethylase. The vanA gene and vanB gene encode the subunit A and subunit B of vanillate demethylase, respectively. The vanK gene encodes the vanillic acid uptake system, and constitutes the vanABK operon together with the vanAB genes (M. T. Chaudhry, et al., Microbiology, 2007, 153:857-865). Therefore, a strain deficient in utilization ability of an objective substance such as vanillin and vanillic acid (FKS0165 strain) was first constructed from C. glutamicum 2256 strain by deleting the vanABK operon. The procedure is shown below.

<1-1> Construction of Plasmid pBS4SΔvanABK56 for Deletion of vanABK Genes

PCR was performed by using the genomic DNA of the C. glutamicum 2256 strain as the template, and the synthetic DNAs of SEQ ID NOS: 51 and 52 as the primers to obtain a PCR product containing an N-terminus side coding region of the vanA gene. Separately, PCR was also performed by using the genomic DNA of the C. glutamicum 2256 strain as the template, and the synthetic DNAs of SEQ ID NOS: 53 and 54 as the primers to obtain a PCR product containing a C-terminus side coding region of the vanK gene. The sequences of SEQ ID NOS: 52 and 53 are partially complementary to each other. Then, the PCR product containing the N-terminus side coding region of the vanA gene and the PCR product containing the C-terminus side coding region of the vanK gene were mixed in approximately equimolar amounts, and inserted into the pBS4S vector (WO2007/046389) treated with BamHI and PstI by using In Fusion HD Cloning Kit (Clontech). With this DNA, competent cells of Escherichia coli JM109 (Takara Bio) were transformed, and the cells were applied to the LB agar medium (5 g/L yeast extract, 10 g/L tryptone, 10 g/L NaCl, 15 g/L agar) containing 100 μM IPTG, 40 μg/mL of X-Gal, and 40 μg/mL of kanamycin, and cultured overnight. Then, white colonies that appeared were picked up, and separated into single colonies to obtain transformants. Plasmids were extracted from the obtained transformants, and one into which the target PCR product was inserted was designated as pBS4SΔvanABK56.

<1-2> Construction of FKS0165 Strain

pBS4SΔvanABK56 obtained above does not contain the region enabling autonomous replication of the plasmid in cells of coryneform bacteria. Therefore, if coryneform bacteria are transformed with this plasmid, a strain in which this plasmid is incorporated into the genome by homologous recombination appears as a transformant, although it occurs at an extremely low frequency. Therefore, pBS4SΔvanABK56 was introduced into the C. glutamicum 2256 strain by the electric pulse method. The cells were applied to the CM-Dex agar medium (5 g/L of glucose, 10 g/L of polypeptone, 10 g/L of yeast extract, 1 g/L of KH₂PO₄, 0.4 g/L of MgSO₄·7H₂O, 0.01 g/L of FeSO₄·7H₂O, 0.01 g/L of MnSO₄·7H₂O, 3 g/L of urea, 1.2 g/L of soybean hydrolysate, 10 μg/L of biotin, 15 g/L of agar, adjusted to pH 7.5 with NaOH) containing 25 μg/mL of kanamycin, and cultured at 31.5° C. It was confirmed by PCR that the grown strain was a once-recombinant strain in which pBS4SΔvanABK56 was incorporated into the genome by homologous recombination. This once-recombinant strain had both the wild-type vanABK genes, and the deficient-type vanABK genes.

The once-recombinant strain was cultured overnight in the CM-Dex liquid medium (having the same composition as that of the CM-Dex agar medium except that it does not contain agar), and the culture broth was applied to the S10 agar medium (100 g/L of sucrose, 10 g/L of polypeptone, 10 g/L of yeast extract, 1 g/L of KH₂PO₄, 0.4 g/L of MgSO₄·7H₂O, 0.01 g/L of FeSO₄·7H₂O, 0.01 g/L of MnSO₄·4-5H₂O, 3 g/L of urea, 1.2 g/L of soybean protein hydrolysate solution, 10 μg/L of biotin, 20 g/L of agar, adjusted to pH 7.5 with NaOH, and autoclaved at 120° C. for 20 minutes), and cultured at 31.5° C. Among the colonies that appeared, a strain that showed kanamycin susceptibility was purified on the CM-Dex agar medium. By preparing genomic DNA from the purified strain, and using it to perform PCR with the synthetic DNAs of SEQ ID NOS: 55 and 56 as the primers, deletion of the vanABK genes was confirmed, and the strain was designated as FKS0165 strain.

<2> Construction of Strain Deficient in Alcohol Dehydrogenase Homologue Genes (FKFC14 Strain)

Subsequently, by using the Corynebacterium glutamicum FKS0165 strain as a parent strain, there was constructed a strain FKFC14, which is deficient in alcohol dehydrogenase homologue genes, i.e. NCgl0324 gene (adhC), NCgl0313 gene (adhE), and NCgl2709 gene (adhA), via the following procedure.

<2-1> Construction of FKFC5 Strain (FKS0165ΔNCgl0324 Strain)

<2-1-1> Construction of Plasmid pBS4SΔ2256adhC for Deletion of NCgl0324 Gene

PCR was performed by using the genomic DNA of the C. glutamicum 2256 strain as the template, and the synthetic DNAs of SEQ ID NOS: 57 and 58 as the primers to obtain a PCR product containing an N-terminus side coding region of the NCgl0324 gene. Separately, PCR was performed by using the genomic DNA of the C. glutamicum 2256 strain as the template, and the synthetic DNAs of SEQ ID NOS: 59 and 60 as the primers to obtain a PCR product containing a C-terminus side coding region of the NCgl0324 gene. The sequences of SEQ ID NOS: 58 and 59 are partially complementary to each other. Then, approximately equimolar amounts of the PCR product containing the N-terminus side coding region of the NCgl0324 gene and the PCR product containing the C-terminus side coding region of the NCgl0324 gene were mixed, and inserted into the pBS4S vector (WO2007/046389) treated with BamHI and PstI by using In Fusion HD Cloning Kit (Clontech). With this DNA, competent cells of Escherichia coli JM109 (Takara Bio) were transformed, and the cells were applied to the LB agar medium containing 100 μM IPTG, 40 μg/mL of X-Gal, and 40 μg/mL of kanamycin, and cultured overnight. Then, white colonies that appeared were picked up, and separated into single colonies to obtain transformants. Plasmids were extracted from the obtained transformants, and one in which the target PCR product was inserted was designated as pBS4SΔ2256adhC.

<2-1-2> Construction of FKFC5 Strain (FKS0165ΔNCgl0324 Strain)

Since pBS4SΔ2256adhC obtained above does not contain the region enabling autonomous replication of the plasmid in cells of coryneform bacteria, if coryneform bacteria are transformed with this plasmid, a strain in which this plasmid is incorporated into the genome by homologous recombination appears as a transformant, although it occurs at an extremely low frequency. Therefore, pBS4SΔ2256adhC was introduced into the C. glutamicum FKS0165 strain by the electric pulse method. The cells were applied to the CM-Dex agar medium containing 25 μg/mL of kanamycin, and cultured at 31.5° C. It was confirmed by PCR that the grown strain was a once-recombinant strain in which pBS4SΔ2256adhC was incorporated into the genome by homologous recombination. This once-recombinant strain had both the wild-type NCgl0324 gene, and the deficient-type NCgl0324 gene.

The once-recombinant strain was cultured overnight in the CM-Dex liquid medium, the culture broth was applied to the S10 agar medium, and culture was performed at 31.5° C. Among the colonies that appeared, a strain that showed kanamycin susceptibility was purified on the CM-Dex agar medium. Genomic DNA was prepared from the purified strain, and used to perform PCR with the synthetic DNAs of SEQ ID NOS: 61 and 62 as the primers to confirm deletion of the NCgl0324 gene, and the strain was designated as FKFC5 strain.

<2-2> Construction of FKFC11 Strain (2256ΔvanABKΔNCgl0324ΔNCgl0313 Strain)

<2-2-1> Construction of Plasmid pBS4SΔ2256adhE for Deletion of NCgl0313 Gene

PCR was performed by using the genomic DNA of the C. glutamicum 2256 strain as the template, and the synthetic DNAs of SEQ ID NOS: 63 and 64 as the primers to obtain a PCR product containing an N-terminus side coding region of the NCgl0313 gene. Separately, PCR was performed by using the genomic DNA of the C. glutamicum 2256 strain as the template, and the synthetic DNAs of SEQ ID NOS: 65 and 66 as the primers to obtain a PCR product containing a C-terminus side coding region of the NCgl0313 gene. The sequences of SEQ ID NOS: 64 and 65 are partially complementary to each other. Then, approximately equimolar amounts of the PCR product containing the N-terminus side coding region of the NCgl0313 gene and the PCR product containing the C-terminus side coding region of the NCgl0313 gene were mixed, and inserted into the pBS4S vector (WO2007/046389) treated with BamHI and PstI by using In Fusion HD Cloning Kit (Clontech). With this DNA, competent cells of Escherichia coli JM109 (Takara Bio) were transformed, and the cells were applied to the LB agar medium containing 100 μM IPTG, 40 μg/mL of X-Gal, and 40 μg/mL of kanamycin, and cultured overnight. Then, white colonies that appeared were picked up, and separated into single colonies to obtain transformants. Plasmids were extracted from the obtained transformants, and one in which the target PCR product was inserted was designated as pBS4SΔ2256adhE.

<2-2-2> Construction of FKFC11 Strain (2256ΔvanABKΔNCgl0324ΔNCgl0313 Strain)

Since pBS4SΔ2256adhE obtained above does not contain the region enabling autonomous replication of the plasmid in cells of coryneform bacteria, if coryneform bacteria are transformed with this plasmid, a strain in which this plasmid is incorporated into the genome by homologous recombination appears as a transformant, although it occurs at an extremely low frequency. Therefore, pBS4SΔ2256adhE was introduced into the C. glutamicum FKFC5 strain by the electric pulse method. The cells were applied to the CM-Dex agar medium containing 25 μg/mL of kanamycin, and cultured at 31.5° C. It was confirmed by PCR that the grown strain was a once-recombinant strain in which pBS4SΔ2256adhE was incorporated into the genome by homologous recombination. This once-recombinant strain had both the wild-type NCgl0313 gene, and the deficient-type NCgl0313 gene.

The once-recombinant strain was cultured overnight in the CM-Dex liquid medium, the culture broth was applied to the S10 agar medium, and culture was performed at 31.5° C. Among the colonies that appeared, a strain that showed kanamycin susceptibility was purified on the CM-Dex agar medium. Genomic DNA was prepared from the purified strain, and used to perform PCR with the synthetic DNAs of SEQ ID NOS: 67 and 68 as the primers to confirm deletion of the NCgl0313 gene, and the strain was designated as FKFC11 strain.

<2-3> Construction of FKFC14 Strain (2256ΔvanABKΔNCgl0324ΔNCgl0313ΔNCgl2709 Strain)

<2-3-1> Construction of Plasmid pBS4SΔ2256adhA for Deletion of NCgl2709 Gene

PCR was performed by using the genomic DNA of the C. glutamicum 2256 strain as the template, and the synthetic DNAs of SEQ ID NOS: 69 and 70 as the primers to obtain a PCR product containing an N-terminus side coding region of the NCgl2709 gene. Separately, PCR was performed by using the genomic DNA of the C. glutamicum 2256 strain as the template, and the synthetic DNAs of SEQ ID NOS: 71 and 72 as the primers to obtain a PCR product containing a C-terminus side coding region of the NCgl2709 gene. The sequences of SEQ ID NOS: 70 and 71 are partially complementary to each other. Then, approximately equimolar amounts of the PCR product containing the N-terminus side coding region of the NCgl2709 gene and the PCR product containing the C-terminus side coding region of the NCgl2709 gene were mixed, and inserted into the pBS4S vector treated with BamHI and PstI by using In Fusion HD Cloning Kit (Clontech). With this DNA, competent cells of Escherichia coli JM109 (Takara Bio) were transformed, and the cells were applied to the LB agar medium containing 100 μM IPTG, 40 μg/mL of X-Gal, and 40 μg/mL of kanamycin, and cultured overnight. Then, white colonies that appeared were picked up, and separated into single colonies to obtain transformants. Plasmids were extracted from the obtained transformants, and one in which the target PCR product was inserted was designated as pBS4SΔ2256adhA.

<2-3-2> Construction of FKFC14 Strain (2256ΔvanABKΔNCgl0324ΔNCgl0313ΔNCgl2709 Strain)

Since pBS4SΔ2256adhA obtained above does not contain the region enabling autonomous replication of the plasmid in cells of coryneform bacteria, if coryneform bacteria are transformed with this plasmid, a strain in which this plasmid is incorporated into the genome by homologous recombination appears as a transformant, although it occurs at an extremely low frequency. Therefore, pBS4SΔ2256adhA was introduced into the C. glutamicum FKFC11 strain by the electric pulse method. The cells were applied to the CM-Dex agar medium containing 25 μg/mL of kanamycin, and cultured at 31.5° C. It was confirmed by PCR that the grown strain was a once-recombinant strain in which pBS4SΔ2256adhA was incorporated into the genome by homologous recombination. This once-recombinant strain had both the wild-type NCgl2709 gene, and the deficient-type NCgl2709 gene.

The once-recombinant strain was cultured overnight in the CM-Dex liquid medium, the culture broth was applied to the S10 agar medium, and culture was performed at 31.5° C. Among the colonies that appeared, a strain that showed kanamycin susceptibility was purified on the CM-Dex agar medium. Genomic DNA was prepared from the purified strain, and used to perform PCR with the synthetic DNAs of SEQ ID NOS: 73 and 74 as the primers to confirm deletion of the NCgl2709 gene, and the strain was designated as FKFC14 strain.

<3> Construction of Strain Deficient in Protocatechuic Acid Dioxygenase Genes (FKFC14ΔpcaGH Strain)

Subsequently, by using the Corynebacterium glutamicum FKFC14 strain as a parent strain, there was constructed a strain FKFC14ΔpcaGH, which is deficient in NCgl2314 gene (pcaG) and NCgl2315 gene (pcaH) encoding the alpha subunit and beta subunit of protocatechuate 3,4-dioxygenase, by outsourcing. The FKFC14ΔpcaGH strain can also be constructed via the following procedure.

<3-1> Construction of Plasmid pBS4SΔ2256pcaGH for Deletion of NCgl2314 and NCgl2315 Genes

NCgl2314 and NCgl2315 genes are adjacent to each other, and therefore these genes can be deleted all together. PCR is performed by using the genomic DNA of the C. glutamicum 2256 strain as the template, and the synthetic DNAs of SEQ ID NOS: 75 and 76 as the primers to obtain a PCR product containing an upstream region of the NCgl2315 gene. Separately, PCR is performed by using the genomic DNA of the C. glutamicum 2256 strain as the template, and the synthetic DNAs of SEQ ID NOS: 77 and 78 as the primers to obtain a PCR product containing a downstream region of the NCgl2314 gene. The sequences of SEQ ID NOS: 76 and 77 are partially complementary to each other. Then, approximately equimolar amounts of the PCR product containing the upstream region of the NCgl2315 gene and the PCR product containing the downstream region of the NCgl2314 gene are mixed, and inserted into the pBS4S vector (WO2007/046389) treated with BamHI and PstI by using In Fusion HD Cloning Kit (Clontech). With this DNA, competent cells of Escherichia coli JM109 (Takara Bio) are transformed, and the cells are applied to the LB agar medium containing 100 μM IPTG, 40 μg/mL of X-Gal, and 40 μg/mL of kanamycin, and cultured overnight. Then, white colonies that appeared are picked up, and separated into single colonies to obtain transformants. Plasmids are extracted from the obtained transformants, and one in which the target PCR product is inserted is designated as pBS4SΔ2256pcaGH.

<3-2> Construction of FKFC14ΔpcaGH Strain

Since pBS4SΔ2256pcaGH obtained above does not contain the region enabling autonomous replication of the plasmid in cells of coryneform bacteria, if coryneform bacteria are transformed with this plasmid, a strain in which this plasmid is incorporated into the genome by homologous recombination appears as a transformant, although it occurs at an extremely low frequency. Therefore, pBS4SΔ2256pcaGH is introduced into the C. glutamicum FKFC14 strain by the electric pulse method. The cells are applied to the CM-Dex agar medium containing 25 μg/mL of kanamycin, and cultured at 31.5° C. It is confirmed by PCR that the grown strain is a once-recombinant strain in which pBS4SΔ2256pcaGH is incorporated into the genome by homologous recombination. This once-recombinant strain has both the wild-type NCgl2314 and NCgl2315 genes, and the deficient-type NCgl2314 and NCgl2315 genes.

The once-recombinant strain is cultured overnight in the CM-Dex liquid medium, the culture medium is applied to the S10 agar medium, and culture is performed at 31.5° C. Among the colonies that appear, a strain that shows kanamycin susceptibility is purified on the CM-Dex agar medium. Genomic DNA is prepared from the purified strain, and used to perform PCR with the synthetic DNAs of SEQ ID NOS: 79 and 80 as the primers to confirm deletion of the NCgl2314 and NCgl2315 genes, and the strain is designated as FKFC14ΔpcaGH strain.

<4> Construction of Ep2_0055 Strain (FKFC14ΔpcaGH P2::NCgl0120 P8::NCgl2048 P4::NCgl0935 Strain P3::NCgl0719)

<4-1> Construction of Ap1_0007 Strain (FKFC14ΔpcaGH P2::NCgl0120 Strain)

Subsequently, by using the Corynebacterium glutamicum FKFC14ΔpcaGH strain as a parent strain, there was constructed a strain Ap1_0007, in which the promoter region of NCgl0120 gene (cysR) encoding a Crp family expression regulatory protein has been replaced with the P2 promoter to enhance the expression of this gene, by outsourcing. The nucleotide sequence of a genomic region containing the P2 promoter in this strain is shown as SEQ ID NO: 108, wherein position 942-1034 corresponds to the P2 promoter. The Ap1_0007 strain can also be constructed via the following procedure.

<4-1-1> Construction of Plasmid pBS4SP2::NCgl0120 for Substitution of NCgl0120 Gene Promoter

PCR is performed by using the genomic DNA of the C. glutamicum 2256 strain as the template, and the synthetic DNAs of SEQ ID NOS: 81 and 82 as the primers to obtain a PCR product containing an upstream region of the NCgl0120 gene. Separately, PCR is performed by using the genomic DNA of the C. glutamicum 2256 strain as the template, and the synthetic DNAs of SEQ ID NOS: 83 and 84 as the primers to obtain a PCR product containing an N-terminus side coding region of the NCgl0120 gene. In addition, a DNA fragment of SEQ ID NO: 85 containing P2 promoter region is obtained by artificial gene synthesis. And then, PCR is performed by using the DNA fragment of SEQ ID NO: 85 as the template, and the synthetic DNAs of SEQ ID NOS: 86 and 87 as the primers to obtain a PCR product containing the P2 promoter. The sequences of SEQ ID NOS: 82 and 86 are partially complementary to each other, and the sequences of SEQ ID NOS: 83 and 87 are partially complementary to each other. Then, approximately equimolar amounts of the PCR product containing the upstream region of the NCgl0120 gene, the PCR product containing the N-terminus side coding region of the NCgl0120 gene, and the PCR product containing the P2 promoter are mixed, and inserted into the pBS4S vector (WO2007/046389) treated with BamHI and PstI by using In Fusion HD Cloning Kit (Clontech). With this DNA, competent cells of Escherichia coli JM109 (Takara Bio) are transformed, and the cells are applied to the LB agar medium containing 100 μM IPTG, 40 μg/mL of X-Gal, and 40 μg/mL of kanamycin, and cultured overnight. Then, white colonies that appeared are picked up, and separated into single colonies to obtain transformants. Plasmids are extracted from the obtained transformants, and one in which the target PCR product is inserted is designated as pBS4SP2::NCgl0120.

<4-1-2> Construction of Ap1_0007 Strain

Since pBS4SP2::NCgl0120 obtained above does not contain the region enabling autonomous replication of the plasmid in cells of coryneform bacteria, if coryneform bacteria are transformed with this plasmid, a strain in which this plasmid is incorporated into the genome by homologous recombination appears as a transformant, although it occurs at an extremely low frequency. Therefore, pBS4SP2::NCgl0120 is introduced into the C. glutamicum FKFC14ΔpcaGH strain by the electric pulse method. The cells are applied to the CM-Dex agar medium containing 25 μg/mL of kanamycin, and cultured at 31.5° C. It is confirmed by PCR that the grown strain is a once-recombinant strain in which pBS4SP2::NCgl0120 is incorporated into the genome by homologous recombination.

The once-recombinant strain is cultured overnight in the CM-Dex liquid medium, the culture medium is applied to the S10 agar medium, and culture is performed at 31.5° C. Among the colonies that appear, a strain that shows kanamycin susceptibility is purified on the CM-Dex agar medium. Genomic DNA is prepared from the purified strain, and used to perform nucleotide sequence analysis to confirm that P2 promoter is located upstream of the NCgl0120 gene, and the strain is designated as Ap1_0007 strain.

<4-2> Construction of Bp1_0112 Strain (FKFC14ΔpcaGH P2::NCgl0120 P8::NCgl2048 Strain)

Subsequently, by using the Corynebacterium glutamicum Ap1_0007 strain as a parent strain, there was constructed a strain Bp1_0112, in which the promoter region of NCgl2048 gene has been replaced with the P8 promoter to attenuate the expression of this gene, by outsourcing. The nucleotide sequence of a genomic region containing the P8 promoter in this strain is shown as SEQ ID NO: 110, wherein position 901-1046 corresponds to the P8 promoter. The Bp1_0112 strain can also be constructed via the following procedure.

<4-2-1> Construction of Plasmid pBS4SP8::NCgl2048 for Substitution of NCgl2048 Gene Promoter

PCR is performed by using the genomic DNA of the C. glutamicum 2256 strain as the template, and the synthetic DNAs of SEQ ID NOS: 112 and 113 as the primers to obtain a PCR product containing an upstream region of the NCgl2048 gene. Separately, PCR is performed by using the genomic DNA of the C. glutamicum 2256 strain as the template, and the synthetic DNAs of SEQ ID NOS: 114 and 115 as the primers to obtain a PCR product containing an N-terminus side coding region of the NCgl2048 gene. In addition, a DNA fragment of SEQ ID NO: 116 containing P8 promoter region is obtained by artificial gene synthesis. And then, PCR is performed by using the DNA fragment of SEQ ID NO: 116 as the template, and the synthetic DNAs of SEQ ID NOS: 117 and 118 as the primers to obtain a PCR product containing the P8 promoter. The sequences of SEQ ID NOS: 113 and 117 are partially complementary to each other, and the sequences of SEQ ID NOS: 114 and 118 are partially complementary to each other. Then, approximately equimolar amounts of the PCR product containing the upstream region of the NCgl2048 gene, the PCR product containing the N-terminus side coding region of the NCgl2048 gene, and the PCR product containing the P8 promoter are mixed, and inserted into the pBS4S vector (WO2007/046389) treated with BamHI and PstI by using In Fusion HD Cloning Kit (Clontech). With this DNA, competent cells of Escherichia coli JM109 (Takara Bio) are transformed, and the cells are applied to the LB agar medium containing 100 μM IPTG, 40 μg/mL of X-Gal, and 40 μg/mL of kanamycin, and cultured overnight. Then, white colonies that appeared are picked up, and separated into single colonies to obtain transformants. Plasmids are extracted from the obtained transformants, and one in which the target PCR product is inserted is designated as pBS4SP8::NCgl2048.

<4-2-2> Construction of Bp1_0112 Strain

Since pBS4SP8::NCgl2048 obtained above does not contain the region enabling autonomous replication of the plasmid in cells of coryneform bacteria, if coryneform bacteria are transformed with this plasmid, a strain in which this plasmid is incorporated into the genome by homologous recombination appears as a transformant, although it occurs at an extremely low frequency. Therefore, pBS4SP8::NCgl2048 is introduced into the C. glutamicum Ap1_0007 strain by the electric pulse method. The cells are applied to the CM-Dex agar medium containing 25 μg/mL of kanamycin, and cultured at 31.5° C. It is confirmed by PCR that the grown strain is a once-recombinant strain in which pBS4SP8::NCgl2048 is incorporated into the genome by homologous recombination.

The once-recombinant strain is cultured overnight in the CM-Dex liquid medium, the culture medium is applied to the S10 agar medium, and culture is performed at 31.5° C. Among the colonies that appear, a strain that shows kanamycin susceptibility is purified on the CM-Dex agar medium. Genomic DNA is prepared from the purified strain, and used to perform nucleotide sequence analysis to confirm that P8 promoter is located upstream of the NCgl2048 gene, and the strain is designated as Bp1_0112 strain.

<4-3> Construction of Dp2_0340 Strain (FKFC14ΔpcaGH P2::NCgl0120 P8::NCgl2048 P4::NCgl0935 Strain)

Subsequently, by using the Corynebacterium glutamicum Bp1_0112 strain as a parent strain, there was constructed a strain Dp2_0340, in which the promoter region of NCgl0935 gene (eno) encoding enolase has been replaced with the P4 promoter to attenuate the expression of this gene, by outsourcing. The nucleotide sequence of a genomic region containing the P4 promoter in this strain is shown as SEQ ID NO: 109, wherein position 872-969 corresponds to the P4 promoter. The Dp2_0340 strain can also be constructed via the following procedure.

<4-3-1> Construction of Plasmid pBS4SP4::NCgl0935 for Substitution of NCgl0935 Gene Promoter

PCR is performed by using the genomic DNA of the C. glutamicum 2256 strain as the template, and the synthetic DNAs of SEQ ID NOS: 121 and 122 as the primers to obtain a PCR product containing an upstream region of the NCgl0935 gene. Separately, PCR is performed by using the genomic DNA of the C. glutamicum 2256 strain as the template, and the synthetic DNAs of SEQ ID NOS: 123 and 124 as the primers to obtain a PCR product containing an N-terminus side coding region of the NCgl0935 gene. In addition, a DNA fragment of SEQ ID NO: 125 containing P4 promoter region is obtained by artificial gene synthesis. And then, PCR is performed by using the DNA fragment of SEQ ID NO: 125 as the template, and the synthetic DNAs of SEQ ID NOS: 126 and 127 as the primers to obtain a PCR product containing the P4 promoter. The sequences of SEQ ID NOS: 122 and 126 are partially complementary to each other, and the sequences of SEQ ID NOS: 123 and 127 are partially complementary to each other. Then, approximately equimolar amounts of the PCR product containing the upstream region of the NCgl0935 gene, the PCR product containing the N-terminus side coding region of the NCgl0935 gene, and the PCR product containing the P4 promoter are mixed, and inserted into the pBS4S vector (WO2007/046389) treated with BamHI and PstI by using In Fusion HD Cloning Kit (Clontech). With this DNA, competent cells of Escherichia coli JM109 (Takara Bio) are transformed, and the cells are applied to the LB agar medium containing 100 μM IPTG, 40 μg/mL of X-Gal, and 40 μg/mL of kanamycin, and cultured overnight. Then, white colonies that appeared are picked up, and separated into single colonies to obtain transformants. Plasmids are extracted from the obtained transformants, and one in which the target PCR product is inserted is designated as pBS4SP4::NCgl0935.

<4-3-2> Construction of Dp2_0340 Strain

Since pBS4SP4::NCgl0935 obtained above does not contain the region enabling autonomous replication of the plasmid in cells of coryneform bacteria, if coryneform bacteria are transformed with this plasmid, a strain in which this plasmid is incorporated into the genome by homologous recombination appears as a transformant, although it occurs at an extremely low frequency. Therefore, pBS4SP4::NCgl0935 is introduced into the C. glutamicum Bp1_0112 strain by the electric pulse method. The cells are applied to the CM-Dex agar medium containing 25 μg/mL of kanamycin, and cultured at 31.5° C. It is confirmed by PCR that the grown strain is a once-recombinant strain in which pBS4SP4::NCgl0935 is incorporated into the genome by homologous recombination.

The once-recombinant strain is cultured overnight in the CM-Dex liquid medium, the culture medium is applied to the S10 agar medium, and culture is performed at 31.5° C. Among the colonies that appear, a strain that shows kanamycin susceptibility is purified on the CM-Dex agar medium. Genomic DNA is prepared from the purified strain, and used to perform nucleotide sequence analysis to confirm that P4 promoter is located upstream of the NCgl0935 gene, and the strain is designated as Dp2_0340 strain.

<4-4> Construction of Ep2_0055 Strain (FKFC14ΔpcaGH P2::NCgl0120 P8::NCgl2048 P4::NCgl0935 P3::NCgl0719 Strain)

Subsequently, by using the Corynebacterium glutamicum Dp2_0340 strain as a parent strain, there was constructed a strain Ep2_0055, in which the promoter region of NCgl0719 gene (sahH) encoding S-adenosyl-L-homocysteine hydrolase has been replaced with the P3 promoter, by outsourcing. The nucleotide sequence the P3 promoter is shown as SEQ ID NO: 111. The Ep2_0055 strain can also be constructed via the following procedure.

<4-4-1> Construction of Plasmid pBS4SP3::NCgl0719 for Substitution of NCgl0719 Gene Promoter

PCR is performed by using the genomic DNA of the C. glutamicum 2256 strain as the template, and the synthetic DNAs of SEQ ID NOS: 138 and 139 as the primers to obtain a PCR product containing an upstream region of the NCgl0719 gene. Separately, PCR is performed by using the genomic DNA of the C. glutamicum 2256 strain as the template, and the synthetic DNAs of SEQ ID NOS: 140 and 141 as the primers to obtain a PCR product containing an N-terminus side coding region of the NCgl0719 gene. In addition, a DNA fragment of SEQ ID NO: 111 containing P3 promoter region is obtained by artificial gene synthesis. And then, PCR is performed by using the DNA fragment of SEQ ID NO: 111 as the template, and the synthetic DNAs of SEQ ID NOS: 142 and 143 as the primers to obtain a PCR product containing the P3 promoter. The sequences of SEQ ID NOS: 139 and 142 are partially complementary to each other, and the sequences of SEQ ID NOS: 140 and 143 are partially complementary to each other. Then, approximately equimolar amounts of the PCR product containing the upstream region of the NCgl0719 gene, the PCR product containing the N-terminus side coding region of the NCgl0719 gene, and the PCR product containing the P3 promoter are mixed, and inserted into the pBS4S vector (WO2007/046389) treated with BamHI and PstI by using In Fusion HD Cloning Kit (Clontech). With this DNA, competent cells of Escherichia coli JM109 (Takara Bio) are transformed, and the cells are applied to the LB agar medium containing 100 μM IPTG, 40 μg/mL of X-Gal, and 40 μg/mL of kanamycin, and cultured overnight. Then, white colonies that appeared are picked up, and separated into single colonies to obtain transformants. Plasmids are extracted from the obtained transformants, and one in which the target PCR product is inserted is designated as pBS4SP3::NCgl0719.

<4-4-2> Construction of Ep2_0055 Strain

Since pBS4SP3::NCgl0719 obtained above does not contain the region enabling autonomous replication of the plasmid in cells of coryneform bacteria, if coryneform bacteria are transformed with this plasmid, a strain in which this plasmid is incorporated into the genome by homologous recombination appears as a transformant, although it occurs at an extremely low frequency. Therefore, pBS4SP3::NCgl0719 is introduced into the C. glutamicum Dp2_0340 strain by the electric pulse method. The cells are applied to the CM-Dex agar medium containing 25 μg/mL of kanamycin, and cultured at 31.5° C. It is confirmed by PCR that the grown strain is a once-recombinant strain in which pBS4SP3::NCgl0719 is incorporated into the genome by homologous recombination.

The once-recombinant strain is cultured overnight in the CM-Dex liquid medium, the culture medium is applied to the S10 agar medium, and culture is performed at 31.5° C. Among the colonies that appear, a strain that shows kanamycin susceptibility is purified on the CM-Dex agar medium. Genomic DNA is prepared from the purified strain, and used to perform nucleotide sequence analysis to confirm that P3 promoter is located upstream of the NCgl0719 gene, and the strain is designated as Ep2_0055 strain.

<4-5> Construction of Ep2_0055ΔsdaA Strain (FKFC14ΔpcaGHΔsdaA P2::NCgl0120 P8::NCgl2048 P4::NCgl0935 P3::NCgl0719 Strain)

Subsequently, by using the Corynebacterium glutamicum Ep2_0055 strain as a parent strain, there was constructed a strain Ep2_0055ΔsdaA, which is deficient in NCgl1583 gene (sdaA) encoding L-serine deaminase.

<4-5-1> Construction of Plasmid pBS4SΔ2256sdaA for Deletion of sdaA Gene

PCR was performed by using the genomic DNA of the C. glutamicum 2256 strain as the template, and the synthetic DNAs of SEQ ID NOS: 148 and 149 as the primers to obtain a PCR product containing an N-terminus side coding region of the sdaA gene. Separately, PCR was performed by using the genomic DNA of the C. glutamicum 2256 strain as the template, and the synthetic DNAs of SEQ ID NOS: 150 and 151 as the primers to obtain a PCR product containing a C-terminus side coding region of the sdaA gene. The sequences of SEQ ID NOS: 149 and 150 are partially complementary to each other. Then, approximately equimolar amounts of the PCR product containing the N-terminus side coding region of the sdaA gene and the PCR product containing the C-terminus side coding region of the sdaA gene were mixed, and inserted into the pBS4S vector treated with BamHI and PstI by using In Fusion HD Cloning Kit (Clontech). With this DNA, competent cells of Escherichia coli JM109 (Takara Bio) were transformed, and the cells were applied to the LB agar medium containing 100 μM IPTG, 40 μg/mL of X-Gal, and 40 μg/mL of kanamycin, and cultured overnight. Then, white colonies that appeared were picked up, and separated into single colonies to obtain transformants. Plasmids were extracted from the obtained transformants, and one in which the target PCR product was inserted was designated as pBS4SΔ2256sdaA.

<4-5-2> Construction of Ep2_0055ΔsdaA Strain (FKFC14ΔpcaGHΔsdaA P2::NCgl0120 P8::NCgl2048 P4::NCgl0935 P3::NCgl0719 Strain)

Since pBS4SΔ2256sdaA obtained above does not contain the region enabling autonomous replication of the plasmid in cells of coryneform bacteria, if coryneform bacteria are transformed with this plasmid, a strain in which this plasmid is incorporated into the genome by homologous recombination appears as a transformant, although it occurs at an extremely low frequency. Therefore, pBS4SΔ2256sdaA was introduced into the C. glutamicum Ep2_0055 strain by the electric pulse method. The cells were applied to the CM-Dex agar medium containing 25 μg/mL of kanamycin, and cultured at 31.5° C. It was confirmed by PCR that the grown strain was a once-recombinant strain in which pBS4SΔ2256sdaA was incorporated into the genome by homologous recombination. This once-recombinant strain had both the wild-type sdaA gene, and the deficient-type sdaA gene.

The once-recombinant strain was cultured overnight in the CM-Dex liquid medium, the culture broth was applied to the S10 agar medium, and culture was performed at 31.5° C. Among the colonies that appeared, a strain that showed kanamycin susceptibility was purified on the CM-Dex agar medium. Genomic DNA was prepared from the purified strain, and used to perform PCR with the synthetic DNAs of SEQ ID NOS: 152 and 153 as the primers to confirm deletion of the sdaA gene, and the strain was designated as Ep2_0055ΔsdaA strain.

<4-6> Construction of Ep2_0055ΔsdaA purH(S37F) Strain (FKFC14ΔpcaGHΔsdaA purH(S37F) P2::NCgl0120 P8::NCgl2048 P4::NCgl0935 P3::NCgl0719 Strain)

The Corynebacterium glutamicum FKFC14ΔpcaGH strain as a parent strain was subjected to mutagenesis with irradiation of UV to thereby construct a strain FKFC14ΔpcaGH purH(S37F). Subsequently, the Corynebacterium glutamicum Ep2_0055ΔsdaA strain as a parent strain was subjected to gene recombination using the genome DNA of the FKFC14ΔpcaGH purH(S37F) strain to thereby construct a strain Ep2_0055ΔsdaA purH(S37F). The FKFC14ΔpcaGH purH(S37F) and Ep2_0055ΔsdaA purH(S37F) strains harbor purH(S37F) gene, which is a mutant purH gene, instead of the wild-type purH gene. The purH(S37F) gene encodes PurH(S37F) protein, which has a mutation that the serine residue at position 37 is replaced with a phenylalanine residue. The nucleotide sequence of the corresponding wild-type purH gene is shown as SEQ ID NO: 134, and the amino acid sequence of the corresponding wild-type purH protein is shown as SEQ ID NO: 135. The nucleotide sequence of the purH(S37F) gene is shown as SEQ ID NO: 136, and the amino acid sequence of the purH(S37F) protein is shown as SEQ ID NO: 137. The Ep2_0055ΔsdaA purH(S37F) strain can also be constructed via the following procedure.

<4-6-1> Construction of Plasmid pBS4SΔ2256purH(S37F) for Introduction of purH(S37F) Mutation

PCR is performed by using the genomic DNA of the C. glutamicum 2256 strain as the template, and the synthetic DNAs of SEQ ID NOS: 154 and 155 as the primers to obtain a PCR product containing an N-terminus side coding region of the purH gene. Separately, PCR is performed by using the genomic DNA of the C. glutamicum 2256 strain as the template, and the synthetic DNAs of SEQ ID NOS: 156 and 157 as the primers to obtain a PCR product containing a C-terminus side coding region of the purH gene. In addition, a DNA fragment of SEQ ID NO: 158 is obtained by artificial gene synthesis. The sequences of SEQ ID NOS: 155 and 158 are partially complementary to each other, and the sequences of SEQ ID NOS: 156 and 158 are partially complementary to each other. Then, approximately equimolar amounts of the PCR product containing the N-terminus side coding region of the purH gene, the DNA fragment of SEQ ID NO: 158, and the PCR product containing the C-terminus side coding region of the purH gene are mixed, and inserted into the pBS4S vector treated with BamHI and PstI by using In Fusion HD Cloning Kit (Clontech). With this DNA, competent cells of Escherichia coli JM109 (Takara Bio) are transformed, and the cells are applied to the LB agar medium containing 100 μM IPTG, 40 μg/mL of X-Gal, and 40 μg/mL of kanamycin, and cultured overnight. Then, white colonies that appeared are picked up, and separated into single colonies to obtain transformants. Plasmids are extracted from the obtained transformants, and one in which the target PCR product is inserted is designated as pBS4SΔ2256purH(S37F).

<4-6-2> Construction of Ep2_0055ΔsdaA purH(S37F) Strain (FKFC14ΔpcaGHΔsdaA purH(S37F) P2::NCgl0120 P8::NCgl2048 P4::NCgl0935 P3::NCgl0719 Strain)

Since pBS4SΔ2256purH(S37F) obtained above does not contain the region enabling autonomous replication of the plasmid in cells of coryneform bacteria, if coryneform bacteria are transformed with this plasmid, a strain in which this plasmid is incorporated into the genome by homologous recombination appears as a transformant, although it occurs at an extremely low frequency. Therefore, pBS4SΔ2256purH(S37F) is introduced into the C. glutamicum Ep2_0055ΔsdaA strain by the electric pulse method. The cells are applied to the CM-Dex agar medium containing 25 μg/mL of kanamycin, and cultured at 31.5° C. It is confirmed by PCR that the grown strain is a once-recombinant strain in which pBS4SΔ2256purH(S37F) is incorporated into the genome by homologous recombination. This once-recombinant strain had both the wild-type purH gene, and the S37F type purH gene.

The once-recombinant strain is cultured overnight in the CM-Dex liquid medium, the culture broth is applied to the S10 agar medium, and culture is performed at 31.5° C. Among the colonies that appeared, a strain that showed kanamycin susceptibility is purified on the CM-Dex agar medium. Genomic DNA is prepared from the purified strain, and used to perform PCR with the synthetic DNAs of SEQ ID NOS: 159 and 160 as the primers to confirm introduction of the purH(S37F) gene, and the strain is designated as Ep2_0055ΔsdaA purH(S37F) strain.

<5> Construction of Plasmid pVK9::PcspB-Omt312 for Expression of Mutant OMT Gene of Niastella koreensis

The plasmid pVK9::PcspB-omt312 was obtained by outsourcing. The plasmid pVK9::PcspB-omt312 harbors a mutant OMT gene of Niastella koreensis codon-optimized for the codon usage of C. glutamicum. This mutant OMT gene encodes a mutant OMT that corresponds to the wild-type OMT of Niastella koreensis provided that a double mutation M36K/L67F has been introduced, specifically, methionine residue (M) at position 36 has been replaced with lysine residue (K) due to codon change from ATG to AAG, and leucine residue (L) at position 67 has been replaced with phenylalanine residue (F) due to codon change from TTG to TTT. This mutant OMT gene can also be referred to as “omt312 gene” and this mutant OMT can also be referred to as “OMT312”. The nucleotide sequence of pVK9::PcspB-omt312 is shown as SEQ ID NO: 132, wherein omt312 gene corresponds to position 4880-5545. The amino acid sequence of OMT312 is shown as SEQ ID NO: 133. pVK9::PcspB-omt312 can also be constructed by artificial gene synthesis.

<6> Construction of Plasmid pVS7::Plac-metK for Expression of metK Gene

The plasmid pVS7::Plac-metK harbors metK gene of the C. glutamicum 2256 strain (ATCC 13869). The nucleotide sequence of the metK gene is shown as SEQ ID NO: 161, and the amino acid sequence of the MetK protein is shown as SEQ ID NO: 162. The plasmid pVS7::Plac-metK was constructed via the following procedure.

PCR was performed by using the genomic DNA of the C. glutamicum 2256 strain as the template, and the synthetic DNAs of SEQ ID NOS: 163 and 164 as the primers to obtain a PCR product containing the metK gene. Then, the PCR product was inserted into the pVS7 vector (WO2013/069634) treated with BamHI and PstI by using In Fusion HD Cloning Kit (Clontech). The pVS7 vector is a shuttle-vector for coryneform bacteria and Escherichia coli. With this DNA, competent cells of Escherichia coli JM109 (Takara Bio) were transformed, and the cells were applied to the LB agar medium containing 100 μM IPTG, 40 μg/mL of X-Gal, and 50 μg/mL of spectinomycin, and cultured overnight. Then, white colonies that appeared were picked up, and separated into single colonies to obtain transformants. Plasmids were extracted from the obtained transformants, and one in which the target PCR product was inserted was designated as pVS7::Plac-metK.

<7> Construction of Vanillic Acid-Producing Strain

A mixture of the plasmid pVK9::PcspB-omt312 and the pVS7 vector, and a mixture of the plasmid pVK9::PcspB-omt312 and the plasmid pVS7::Plac-metK were each introduced into the C. glutamicum Ep2_0055ΔsdaA purH(S37F) strain by the electric pulse method. The cells were applied to the CM-Dex agar medium containing 25 μg/mL of kanamycin and 50 μg/mL of spectinomycin, and cultured at 31.5° C. The grown strains were designated as Ep2_0055ΔsdaA purH(S37F)/pVK9::PcspB-omt312+pVS7 and Ep2_0055 ΔsdaA purH(S37F)/pVK9::PcspB-omt312+pVS7::Plac-metK, respectively.

These strains were each inoculated into 4 mL of the CM-Dex liquid medium containing 25 μg/mL of kanamycin and 50 μg/mL of spectinomycin contained in a test tube, and cultured at 31.5° C. with shaking for about 16 hr. A 0.8 mL aliquot of the obtained culture broth was mixed with 0.8 mL of 40% glycerol aqueous solution to obtain a glycerol stock, and stored at −80° C.

<8> Vanillic Acid Production by C. glutamicum Ep2_0055ΔsdaA purH(S37F)/pVK9::PcspB-Omt312+pVS7 and Ep2_0055ΔsdaA purH(S37F)/pVK9::PcspB-Omt312+pVS7::Plac-metK Strains

A 5 μL aliquot of each of the glycerol stocks of the Ep2_0055ΔsdaA purH(S37F)/pVK9::PcspB-omt312+pVS7 and Ep2_0055ΔsdaA purH(S37F)/pVK9::PcspB-omt312+pVS7::Plac-metK strains was inoculated into 0.5 mL of the CM-Dex w/o mameno medium (5 g/L of glucose, 10 g/L of Polypeptone, 10 g/L of Yeast Extract, 1 g/L of KH₂PO₄, 0.4 g/L of MgSO₄·7H₂O, 0.01 g/L of FeSO₄·7H₂O, 0.01 g/L of MnSO₄·7H₂O, 3 g/L of urea, 10 μg/L of biotin, adjusted to pH 7.5 with KOH) containing 25 μg/mL of kanamycin and 50 μg/mL of spectinomycin contained in 2.0 mL DEEP WELL PLATE, and cultured at 30° C. with shaking for 16 hr as preculture. A 0.1 mL aliquot of the obtained preculture broth was inoculated into 0.4 mL of a vanillic acid production medium (75 g/L of glucose, 0.6 g/L of MgSO₄·7H₂O, 6.3 g/L of (NH₄)₂SO₄, 2.5 g/L of KH₂PO₄, 12.5 mg/L of FeSO₄·7H₂O, 12.5 mg/L of MnSO₄·4-5H₂O, 2.5 g/L of Yeast Extract, 150 μg/L of Vitamin B1, 150 μg/L of Biotin, 6.9 g/L of Protocatechuic acid, adjusted to pH 7 with KOH, and then mixed with 30 g/L of CaCO₃ (sterilized with hot air at 180° C. for 3 hours)) containing 25 μg/mL of kanamycin and 50 μg/mL of spectinomycin contained in 2.0 mL DEEP WELL PLATE, and cultured at 30° C. with shaking for 24 hr.

At the completion of the culture, the concentration of vanillic acid in the medium was analyzed by using Ultra Performance Liquid Chromatography NEXERA X2 System (SHIMADZU) with the following conditions. In addition, the optical density (OD) was measured at 600 nm by using Spectra Max 190 (Molecular Devices).

Conditions of UPLC analysis

Column: KINETEX 2.6 μm XB-C18, 150×30 mm (Phenomenex)

Oven temperature: 40° C.

Mobile phase (A): 0.1% Trifluoroacetic acid

Mobile phase (B): 0.1% Trifluoroacetic acid/80% acetonitrile

Gradient program (time, A (%), B (%)): (0, 90, 10)→(3, 80, 20)

Flow rate: 1.5 ml/min

The results are shown in Table 1. The vanillic acid concentration in the medium observed for the Ep2_0055ΔsdaA purH(S37F)/pVK9::PcspB-omt312+pVS7::Plac-metK strain was about 1.04 times as high as that observed for the Ep2_0055ΔsdaA purH(S37F)/pVK9::PcspB-omt312+pVS7 strain. Also, the vanillic acid productivity per OD observed for the Ep2_0055ΔsdaA purH(S37F)/pVK9::PcspB-omt312+pVS7::Plac-metK strain was about 1.03 times as high as that observed for the Ep2_0055ΔsdaA purH(S37F)/pVK9::PcspB-omt312+pVS7 strain.

TABLE 1 Vanillic acid production by C. glutamicum vanillic acid-producing strains Concentration Productivity of of generated vanillic acid vanillic acid (mg/L, h, Strain OD (mg/L) final OD) Ep2_0055ΔsdaA 33.2 ± 2.2 820 ± 9.8 1.06 ± 0.059 purH(S37F)/ pVK9::PcspB-omt312 + pVS7 Ep2_0055ΔsdaA 32.4 ± 1.8 850 ± 8.0 1.09 ± 0.071 purH(S37F)/ pVK9::PcspB-omt312 + pVS7::Plac-metK

Example 2: Vanillic Acid Production by C. glutamicum Strain Having Enhanced Expression of metE Gene Encoding Methionine Synthase

In this example, a strain having an enhanced expression of metE gene encoding methionine synthase was constructed from the Corynebacterium glutamicum 2256 strain (ATCC 13869) as a parent strain, and vanillic acid production was performed with the constructed strain.

<1> Construction of C. glutamicum Ns1_0003 Strain (FKFC14ΔpcaGH P2::NCgl0120 P8::NCgl2048 P4::NCgl0935 P3::NCgl0719 purH(S37F) Strain)

The Corynebacterium glutamicum Ns1_0003 strain, which corresponds to the C. glutamicum Ep2_0055 strain provided that the Ns1_0003 strain harbors the purH(S37F) gene, was obtained by outsourcing. The Ns1_0003 strain can also be constructed via the following procedure.

By using the Ep2_0055 strain as a parent strain, the wild-type purH gene thereof is replaced with the purH(S37F) gene in the same manner as described in Example 1<4-6-2>, and the obtained strain harboring the purH(S37F) gene is designated as Ns1_0003 strain.

<2> Construction of Plasmid pZK1::PcspB-OMT312-PmsrA-MetE-EC for Co-Expression of Mutant OMT Gene and metE Gene

<2-1> Construction of Plasmid pZK1::PcspB-OMT312

pZK1::PcspB-OMT312 was constructed from pVK9::PcspB-omt312 in order to introduce the tcg0610 terminator sequence from Corynebacterium glutamicum ATCC 13032 and remove a known tn10 transposon targeting site. PCR was performed using synthetic DNAs of SEQ ID NOS: 175 and 176 as primers and pVK9::PcspB-omt312 as the template. This PCR product was then phosphorylated using T4 polynucleotide kinase (New England Biolabs) and the resulting phosphorylated blunt ends were self-ligated using a Quick Ligation Kit (New England Biolabs). The resulting ligation mix was transformed into Escherichia coli 10-beta competent cells (New England Biolabs). The transformed cell mix was applied to LB agar medium containing 25 μg/mL of kanamycin, and cultured overnight. Single colonies were picked into liquid LB medium containing kanamycin and grown overnight, and plasmids were extracted.

Sanger sequencing was performed to confirm that the sequence of the resulting plasmids was as expected, and a plasmid with the correct sequence was designated pZK1::PcspB-OMT312.

<2-2> Construction of Plasmid pZK1::PcspB-OMT312-PmsrA-MetE-EC

PCR was performed by using synthetic DNAs of SEQ ID NOS: 177 and 178 as primers and pZK1::PcspB-OMT312 as the template to amplify a vector backbone. A synthetic DNA of SEQ ID NO: 179 containing the cspB promoter, the metE gene from Escherichia coli, and the terminator tcg0610 from Corynebacterium glutamicum ATCC 13032 was obtained by outsourcing. The codon bias was optimized by weighted random selections using a Corynebacterium glutamicum ATCC 13032 codon usage table. This synthetic DNA was cloned into the vector backbone using a Gibson Assembly Cloning Kit (New England Biolabs) according to the manufacturer's protocols. The resulting assembly mix was transformed into Escherichia coli 10-beta competent cells (New England Biolabs). The transformed cell mix was applied to LB agar medium containing 25 μg/mL of kanamycin, and cultured overnight. Single colonies were picked into liquid LB medium containing kanamycin and grown overnight, and plasmids were extracted. Sanger sequencing was performed to confirm that the sequence of the resulting plasmids was as expected, and a plasmid with the correct sequence was designated pZK1::PcspB-OMT312-PmsrA-MetE-EC.

<3> Construction of Vanillic Acid-Producing Strain

Corynebacterium glutamicum vanillic acid-producing strains, Ns1_0003_Rg (Ns1_0003/pZK1::PcspB-omt312) and Ph2_0011_Rg (Ns1_0003/pZK1::PcspB-OMT312-PmsrA-MetE-EC), were obtained by outsourcing. These strains can also be constructed via the following procedure.

The plasmid pZK1::PcspB-omt312 and the plasmid pZK1::PcspB-OMT312-PmsrA-MetE-EC are each introduced into the C. glutamicum Ns1_0003 strain by the electric pulse method. The cells are applied to the CM-Dex agar medium containing 25 μg/mL of kanamycin, and cultured at 31.5° C. The grown strains are designated as Ns1_0003_Rg and Ph2_0011_Rg, respectively.

These strains are each inoculated into 4 mL of the CM-Dex liquid medium containing 25 μg/mL of kanamycin contained in a test tube, and cultured at 31.5° C. with shaking for about 16 hr. A 0.8 mL aliquot of the obtained culture broth was mixed with 0.8 mL of 40% glycerol aqueous solution to obtain a glycerol stock, and stored at −80° C.

<4> Vanillic Acid Production by C. glutamicum Ns1_0003_Rg and pH2_0011_Rg Strains

A 5 μL aliquot of each of the glycerol stocks of the Ns1_0003_Rg and Ph2_0011_Rg strains was inoculated into 0.5 mL of the CM-Dex w/o mameno medium containing 25 μg/mL of kanamycin contained in 2.0 mL DEEP WELL PLATE, and cultured at 30° C. with shaking for 16 hr as preculture. A 0.1 mL aliquot of the obtained preculture broth was inoculated into 0.4 mL of the vanillic acid production medium containing 25 μg/mL of kanamycin contained in 2.0 mL DEEP WELL PLATE, and cultured at 30° C. with shaking for 24 hr.

At the completion of the culture, the concentration of vanillic acid in the medium was analyzed by using Ultra Performance Liquid Chromatography NEXERA X2 System (SHIMADZU) with the same conditions as described in Example 1<8>. In addition, the optical density (OD) was measured at 600 nm by using Spectra Max 190 (Molecular Devices).

The results are shown in Table 2. The vanillic acid concentration in the medium observed for the Ph2_0011_Rg strain was about 1.28 times as high as that observed for the Ns1_0003_Rg strain. Also, the vanillic acid productivity per OD observed for the Ph2_0011_Rg strain was about 1.25 times as high as that observed for the Ns1_0003_Rg strain.

TABLE 2 Vanillic acid production by C. glutamicum vanillic acid-producing strains Concentration Productivity of of generated vanillic acid vanillic acid (mg/L, h, Strain OD (mg/L) final OD) Ns1_0003_Rg 30.6 ± 0.0 633 ± 3.1 0.86 ± 0.004 Ph2_0011_Rg 31.2 ± 0.9 808 ± 5.6 1.08 ± 0.023

Example 3: Vanillic Acid Production by C. glutamicum Strain Having Enhanced Expression of metH Gene Encoding Methionine Synthase

In this example, a strain having an enhanced expression of metH gene encoding methionine synthase was constructed from the Corynebacterium glutamicum 2256 strain (ATCC 13869) as a parent strain, and vanillic acid production was performed with the constructed strain.

<1> Construction of Plasmid pZK1::PcspB-OMT312-PmsrA-MetH-CG for Co-Expression of Mutant OMT Gene and metH Gene

PCR was performed by using synthetic DNAs of SEQ ID NOS: 177 and 178 as primers and pZK1::PcspB-OMT312 as the template to amplify a vector backbone. A synthetic DNA of SEQ ID NO: 180 containing the cspB promoter, the metH gene (cg1701) from Corynebacterium glutamicum, and the terminator tcg0610 from Corynebacterium glutamicum ATCC 13032 was obtained by outsourcing. The codon bias was optimized by weighted random selections using a Corynebacterium glutamicum ATCC 13032 codon usage table. This synthetic DNA was cloned into the vector backbone using a Gibson Assembly Cloning Kit (New England Biolabs) according to the manufacturer's protocols. The resulting assembly mix was transformed into Escherichia coli 10-beta competent cells (New England Biolabs). The transformed cell mix was applied to LB agar medium containing 25 μg/mL of kanamycin, and cultured overnight. Single colonies were picked into liquid LB medium containing kanamycin and grown overnight, and plasmids were extracted. Sanger sequencing was performed to confirm that the sequence of the resulting plasmids was as expected, and a plasmid with the correct sequence was designated pZK1::PcspB-OMT312-PmsrA-MetH-CG.

<2> Construction of Vanillic Acid-Producing Strain

Corynebacterium glutamicum vanillic acid-producing strains, Ns1_0003_Rg (Ns1_0003/pZK1::PcspB-omt312) and Ph2_0003_Rg (Ns1_0003/pZK1::PcspB-OMT312-PmsrA-MetH-CG), were obtained by outsourcing. These strains can also be constructed via the following procedure.

The plasmid pZK1::PcspB-omt312 and the plasmid pZK1::PcspB-OMT312-PmsrA-MetH-CG are each introduced into the C. glutamicum Ns1_0003 strain by the electric pulse method. The cells are applied to the CM-Dex agar medium containing 25 μg/mL of kanamycin, and cultured at 31.5° C. The grown strains are designated as Ns1_0003_Rg and Ph2_0003_Rg, respectively.

These strains are each inoculated into 4 mL of the CM-Dex liquid medium containing 25 μg/mL of kanamycin contained in a test tube, and cultured at 31.5° C. with shaking for about 16 hr. A 0.8 mL aliquot of the obtained culture broth was mixed with 0.8 mL of 40% glycerol aqueous solution to obtain a glycerol stock, and stored at −80° C.

<4> Vanillic Acid Production by C. glutamicum Ns1_0003_Rg and pH2_0003_Rg Strains

A 5 μL aliquot of each of the glycerol stocks of the Ns1_0003_Rg and Ph2_0003_Rg strains was inoculated into 0.5 mL of the CM-Dex w/o mameno medium containing 25 μg/mL of kanamycin contained in 2.0 mL DEEP WELL PLATE, and cultured at 30° C. with shaking for 16 hr as preculture. A 0.1 mL aliquot of the obtained preculture broth was inoculated into 0.4 mL of the vanillic acid production medium containing 25 μg/mL of kanamycin contained in 2.0 mL DEEP WELL PLATE, and cultured at 30° C. with shaking for 24 hr.

At the completion of the culture, the concentration of vanillic acid in the medium was analyzed by using Ultra Performance Liquid Chromatography NEXERA X2 System (SHIMADZU) with the same conditions as described in Example 1<8>. In addition, the optical density (OD) was measured at 600 nm by using Spectra Max 190 (Molecular Devices).

The results are shown in Table 3. The vanillic acid concentration in the medium observed for the Ph2_0003_Rg strain was about 1.15 times as high as that observed for the Ns1_0003_Rg strain. Also, the vanillic acid productivity per OD observed for the Ph2_0003_Rg strain was about 1.16 times as high as that observed for the Ns1_0003_Rg strain.

TABLE 3 Vanillic acid production by C. glutamicum vanillic acid-producing strains Concentration Productivity of of generated vanillic acid vanillic acid (mg/L, h, Strain OD (mg/L) final OD) Ns1_0003_Rg 30.6 ± 0.0 633 ± 3.1 0.86 ± 0.004 Ph2_0003_Rg 30.2 ± 0.4 725 ± 7.3 1.00 ± 0.022

Example 4: Vanillic Acid Production by C. glutamicum Strain Having Enhanced Expression of metF Gene Encoding 5,10-Methylenetetrahydrofolate Reductase

In this example, a strain having an enhanced expression of metF gene encoding 5,10-methylenetetrahydrofolate reductase was constructed from the Corynebacterium glutamicum 2256 strain (ATCC 13869) as a parent strain, and vanillic acid production was performed with the constructed strain.

<1> Construction of Plasmids pZK1::PcspB-OMT312-PmsrA-MetF-CG and pZK1::PcspB-OMT312-PmsrA-MetF-SC for Co-Expression of Mutant OMT Gene and metE Gene

<1-1> Construction of Plasmid pZK1::PcspB-OMT312-PmsrA-MetF-CG

PCR was performed by using synthetic DNAs of SEQ ID NOS: 177 and 178 as primers and pZK1::PcspB-OMT312 as the template to amplify a vector backbone. A synthetic DNA of SEQ ID NO: 181 containing the cspB promoter, the metF gene (NCgl2091, partial) from Corynebacterium glutamicum, and the terminator tcg0610 from Corynebacterium glutamicum ATCC 13032 was obtained by outsourcing. The codon bias was optimized by weighted random selections using a Corynebacterium glutamicum ATCC 13032 codon usage table. This metF gene encodes the amino acid sequence shown as SEQ ID NO: 172, which is a partial amino acid sequence of the MetF protein of the C. glutamicum ATCC 13869 strain. This synthetic DNA was cloned into the vector backbone using a Gibson Assembly Cloning Kit (New England Biolabs) according to the manufacturer's protocols. The resulting assembly mix was transformed into Escherichia coli 10-beta competent cells (New England Biolabs). The transformed cell mix was applied to LB agar medium containing 25 μg/mL of kanamycin, and cultured overnight. Single colonies were picked into liquid LB medium containing kanamycin and grown overnight, and plasmids were extracted. Sanger sequencing was performed to confirm that the sequence of the resulting plasmids was as expected, and a plasmid with the correct sequence was designated pZK1::PcspB-OMT312-PmsrA-MetF-CG.

<1-2> Construction of the Plasmid pZK1::PcspB-OMT312-PmsrA-MetF-SC

PCR was performed by using synthetic DNAs of SEQ ID NOS: 177 and 178 as primers and pZK1::PcspB-OMT312 as the template to amplify a vector backbone. A synthetic DNA of SEQ ID NO: 182 containing the cspB promoter, the metF gene (MET13) from Saccharomyces cerevisiae, and the terminator tcg0610 from Corynebacterium glutamicum ATCC 13032 was obtained by outsourcing. The codon bias was optimized by weighted random selections using a Corynebacterium glutamicum ATCC 13032 codon usage table. This synthetic DNA was cloned into the vector backbone using a Gibson Assembly Cloning Kit (New England Biolabs) according to the manufacturer's protocols. The resulting assembly mix was transformed into Escherichia coli 10-beta competent cells (New England Biolabs). The transformed cell mix was applied to LB agar medium containing 25 μg/mL of kanamycin, and cultured overnight. Single colonies were picked into liquid LB medium containing kanamycin and grown overnight, and plasmids were extracted. Sanger sequencing was performed to confirm that the sequence of the resulting plasmids was as expected, and a plasmid with the correct sequence was designated pZK1::PcspB-OMT312-PmsrA-MetF-SC.

<2> Construction of Vanillic Acid-Producing Strain

Corynebacterium glutamicum vanillic acid-producing strains, Ns1_0003_Rg (Ns1_0003/pZK1::PcspB-omt312), Ph2_0028_Rg (Ns1_0003/pZK1::PcspB-OMT312-PmsrA-MetF-CG), and Ph2_0009_Rg (Ns1_0003/pZK1::PcspB-OMT312-PmsrA-MetF-SC), were obtained by outsourcing. These strains can also be constructed via the following procedure.

The plasmid pZK1::PcspB-omt312, the plasmid pZK1::PcspB-OMT312-PmsrA-MetF-CG, and the plasmid pZK1::PcspB-OMT312-PmsrA-MetF-SC are each introduced into the C. glutamicum Ns1_0003 strain by the electric pulse method. The cells are applied to the CM-Dex agar medium containing 25 μg/mL of kanamycin, and cultured at 31.5° C. The grown strains are designated as Ns1_0003_Rg, Ph2_0028_Rg, and Ph2_0009_Rg, respectively.

These strains are each inoculated into 4 mL of the CM-Dex liquid medium containing 25 μg/mL of kanamycin contained in a test tube, and cultured at 31.5° C. with shaking for about 16 hr. A 0.8 mL aliquot of the obtained culture broth was mixed with 0.8 mL of 40% glycerol aqueous solution to obtain a glycerol stock, and stored at −80° C.

<4> Vanillic Acid Production by C. glutamicum Ns1_0003_Rg, pH2_0028_Rg, and pH2_0009_Rg Strains

A 5 μL aliquot of each of the glycerol stocks of the Ns1_0003_Rg, Ph2_0028_Rg, and Ph2_0009_Rg strains was inoculated into 0.5 mL of the CM-Dex w/o mameno medium containing 25 μg/mL of kanamycin contained in 2.0 mL DEEP WELL PLATE, and cultured at 30° C. with shaking for 16 hr as preculture. A 0.1 mL aliquot of the obtained preculture broth was inoculated into 0.4 mL of the vanillic acid production medium containing 25 μg/mL of kanamycin contained in 2.0 mL DEEP WELL PLATE, and cultured at 30° C. with shaking for 24 hr.

At the completion of the culture, the concentration of vanillic acid in the medium was analyzed by using Ultra Performance Liquid Chromatography NEXERA X2 System (SHIMADZU) with the same conditions as described in Example 1<8>. In addition, the optical density (OD) was measured at 600 nm by using Spectra Max 190 (Molecular Devices).

The results are shown in Table 4. The vanillic acid concentration in the medium observed for the Ph2_0028_Rg strain was about 1.25 times as high as that observed for the Ns1_0003_Rg strain. Also, the vanillic acid productivity per OD observed for the Ph2_0028_Rg strain was about 1.26 times as high as that observed for the Ns1_0003_Rg strain. The vanillic acid concentration in the medium observed for the Ph2_0009_Rg strain was about 1.34 times as high as that observed for the Ns1_0003_Rg strain. Also, the vanillic acid productivity per OD observed for the Ph2_0009_Rg strain was about 1.21 times as high as that observed for the Ns1_0003_Rg strain.

TABLE 4 Vanillic acid production by C. glutamicum vanillic acid-producing strains Concentration Productivity of of generated vanillic acid vanillic acid (mg/L, h, Strain OD (mg/L) final OD) Ns1_0003_Rg 30.6 ± 0.0 633 ± 3.1 0.86 ± 0.004 Ph2_0028_Rg 30.4 ± 0.4 791 ± 5.6 1.09 ± 0.011 Ph2_0009_Rg 33.8 ± 1.3  845 ± 18.0 1.04 ± 0.061

INDUSTRIAL APPLICABILITY

According to the present invention, an ability of a microorganism for producing an objective substance such as vanillin and vanillic acid can be improved, and the objective substance can be efficiently produced.

EXPLANATION OF SEQUENCE LISTING

SEQ ID NOS:

1: Nucleotide sequence of aroG gene of Escherichia coli MG1655

2: Amino acid sequence of AroG protein of Escherichia coli MG1655

3: Nucleotide sequence of aroB gene of Escherichia coli MG1655

4: Amino acid sequence of AroB protein of Escherichia coli MG1655

5: Nucleotide sequence of aroD gene of Escherichia coli MG1655

6: Amino acid sequence of AroD protein of Escherichia coli MG1655

7: Nucleotide sequence of asbF gene of Bacillus thuringiensis BMB171

8: Amino acid sequence of AsbF protein of Bacillus thuringiensis BMB171

9: Nucleotide sequence of tyrR gene of Escherichia coli MG1655

10: Amino acid sequence of TyrR protein of Escherichia coli MG1655

11-14: Nucleotide sequences of transcript variants 1 to 4 of OMT gene of Homo sapiens

15: Amino acid sequence of OMT isoform (MB-COMT) of Homo sapiens

16: Amino acid sequence of OMT isoform (S-COMT) of Homo sapiens

17: Nucleotide sequence of ACAR gene of Nocardia brasiliensis

18: Amino acid sequence of ACAR protein of Nocardia brasiliensis

19: Nucleotide sequence of ACAR gene of Nocardia brasiliensis

20: Amino acid sequence of ACAR protein of Nocardia brasiliensis

21: Nucleotide sequence of entD gene of Escherichia coli MG1655

22: Amino acid sequence of EntD protein of Escherichia coli MG1655

23: Nucleotide sequence of PPT gene of Corynebacterium glutamicum ATCC 13032

24: Amino acid sequence of PPT protein of Corynebacterium glutamicum ATCC 13032

25: Nucleotide sequence of vanK gene of Corynebacterium glutamicum 2256 (ATCC 13869)

26: Amino acid sequence of VanK protein of Corynebacterium glutamicum 2256 (ATCC 13869)

27: Nucleotide sequence of pcaK gene of Corynebacterium glutamicum 2256 (ATCC 13869)

28: Amino acid sequence of PcaK protein of Corynebacterium glutamicum 2256 (ATCC 13869)

29: Nucleotide sequence of vanA gene of Corynebacterium glutamicum 2256 (ATCC 13869)

30: Amino acid sequence of VanA protein of Corynebacterium glutamicum 2256 (ATCC 13869)

31: Nucleotide sequence of vanB gene of Corynebacterium glutamicum 2256 (ATCC 13869)

32: Amino acid sequence of VanB protein of Corynebacterium glutamicum 2256 (ATCC 13869)

33: Nucleotide sequence of pcaG gene of Corynebacterium glutamicum ATCC 13032

34: Amino acid sequence of PcaG protein of Corynebacterium glutamicum ATCC 13032

35: Nucleotide sequence of pcaH gene of Corynebacterium glutamicum ATCC 13032

36: Amino acid sequence of PcaH protein of Corynebacterium glutamicum ATCC 13032

37: Nucleotide sequence of yqhD gene of Escherichia coli MG1655

38: Amino acid sequence of YqhD protein of Escherichia coli MG1655

39: Nucleotide sequence of NCgl0324 gene of Corynebacterium glutamicum 2256 (ATCC 13869)

40: Amino acid sequence of NCgl0324 protein of Corynebacterium glutamicum 2256 (ATCC 13869)

41: Nucleotide sequence of NCgl0313 gene of Corynebacterium glutamicum 2256 (ATCC 13869)

42: Amino acid sequence of NCgl0313 protein of Corynebacterium glutamicum 2256 (ATCC 13869)

43: Nucleotide sequence of NCgl2709 gene of Corynebacterium glutamicum 2256 (ATCC 13869)

44: Amino acid sequence of NCgl2709 protein of Corynebacterium glutamicum 2256 (ATCC 13869)

45: Nucleotide sequence of NCgl0219 gene of Corynebacterium glutamicum ATCC 13032

46: Amino acid sequence of NCgl0219 protein of Corynebacterium glutamicum ATCC 13032

47: Nucleotide sequence of NCgl2382 gene of Corynebacterium glutamicum ATCC 13032

48: Amino acid sequence of NCgl2382 protein of Corynebacterium glutamicum ATCC 13032

49: Nucleotide sequence of aroE gene of Escherichia coli MG1655

50: Amino acid sequence of AroE protein of Escherichia coli MG1655

51-84: Primers

85: Nucleotide sequence of DNA fragment containing P2 promoter region

86 and 87: Primers

88: Nucleotide sequence of cysI gene of Corynebacterium glutamicum 2256 (ATCC 13869)

89: Amino acid sequence of CysI protein of Corynebacterium glutamicum 2256 (ATCC 13869)

90: Nucleotide sequence of cysX gene of Corynebacterium glutamicum 2256 (ATCC 13869)

91: Amino acid sequence of CysX protein of Corynebacterium glutamicum 2256 (ATCC 13869)

92: Nucleotide sequence of cysH gene of Corynebacterium glutamicum 2256 (ATCC 13869)

93: Amino acid sequence of CysH protein of Corynebacterium glutamicum 2256 (ATCC 13869)

94: Nucleotide sequence of cysD gene of Corynebacterium glutamicum 2256 (ATCC 13869)

95: Amino acid sequence of CysD protein of Corynebacterium glutamicum 2256 (ATCC 13869)

96: Nucleotide sequence of cysN gene of Corynebacterium glutamicum 2256 (ATCC 13869)

97: Amino acid sequence of CysN protein of Corynebacterium glutamicum 2256 (ATCC 13869)

98: Nucleotide sequence of cysY gene of Corynebacterium glutamicum 2256 (ATCC 13869)

99: Amino acid sequence of CysY protein of Corynebacterium glutamicum 2256 (ATCC 13869)

100: Nucleotide sequence of cysZ gene of Corynebacterium glutamicum 2256 (ATCC 13869)

101: Amino acid sequence of CysZ protein of Corynebacterium glutamicum 2256 (ATCC 13869)

102: Nucleotide sequence of fpr2 gene of Corynebacterium glutamicum 2256 (ATCC 13869)

103: Amino acid sequence of Fpr2 protein of Corynebacterium glutamicum 2256 (ATCC 13869)

104: Nucleotide sequence of cysR gene of Corynebacterium glutamicum 2256 (ATCC 13869)

105: Amino acid sequence of CysR protein of Corynebacterium glutamicum 2256 (ATCC 13869)

106: Nucleotide sequence of ssuR gene of Corynebacterium glutamicum 2256 (ATCC 13869)

107: Amino acid sequence of SsuR protein of Corynebacterium glutamicum 2256 (ATCC 13869)

108: Nucleotide sequence containing P2 promoter

109: Nucleotide sequence containing P4 promoter

110: Nucleotide sequence containing P8 promoter

111: Nucleotide sequence containing P3 promoter

112-115: Primers

116: Nucleotide sequence of DNA fragment containing P8 promoter region

117 and 118: Primers

119: Nucleotide sequence of NCgl2048 gene of Corynebacterium glutamicum 2256 (ATCC 13869)

120: Amino acid sequence of NCgl2048 protein of Corynebacterium glutamicum 2256 (ATCC 13869)

121-124: Primers

125: Nucleotide sequence of DNA fragment containing P4 promoter region

126 and 127: Primers

128: Nucleotide sequence of eno gene of Corynebacterium glutamicum 2256 (ATCC 13869)

129: Amino acid sequence of Eno protein of Corynebacterium glutamicum 2256 (ATCC 13869)

130: Nucleotide sequence of OMT gene of Niastella koreensis

131: Amino acid sequence of OMT of Niastella koreensis

132: Nucleotide sequence of pVK9::PcspB-omt312

133: Amino acid sequence of OMT312

134: Nucleotide sequence of purH gene of Corynebacterium glutamicum 2256 (ATCC 13869)

135: Amino acid sequence of PurH protein of Corynebacterium glutamicum 2256 (ATCC 13869)

136: Nucleotide sequence of purH(S37F) gene (mutant purH gene)

137: Amino acid sequence of purH(S37F) protein (mutant purH protein)

138-143: Primers

144: Nucleotide sequence of sahH gene of Corynebacterium glutamicum 2256 (ATCC 13869)

145: Amino acid sequence of SahH protein of Corynebacterium glutamicum 2256 (ATCC 13869)

146: Nucleotide sequence of sdaA gene of Corynebacterium glutamicum 2256 (ATCC 13869)

147: Amino acid sequence of SdaA protein of Corynebacterium glutamicum 2256 (ATCC 13869)

148-157: Primers

158: Nucleotide sequence of DNA fragment

159 and 160: Primers

161: Nucleotide sequence of metK gene of Corynebacterium glutamicum 2256 (ATCC 13869)

162: Amino acid sequence of MetK protein of Corynebacterium glutamicum 2256 (ATCC 13869)

163 and 164: Primers

165: Nucleotide sequence of metE gene of Escherichia coli MG1655

166: Amino acid sequence of MetE protein of Escherichia coli MG1655

167: Nucleotide sequence of metH gene of Escherichia coli MG1655

168: Amino acid sequence of MetH protein of Escherichia coli MG1655

169: Nucleotide sequence of metH gene of Corynebacterium glutamicum ATCC 13032

170: Amino acid sequence of MetH protein of Corynebacterium glutamicum ATCC 13032

171: Nucleotide sequence of partial metF gene of Corynebacterium glutamicum 2256 (ATCC 13869)

172: Amino acid sequence of partial MetF protein of Corynebacterium glutamicum 2256 (ATCC 13869)

173: Nucleotide sequence of metF gene of Saccharomyces cerevisiae S288c

174: Amino acid sequence of MetF protein of Saccharomyces cerevisiae S288c

175-178: Primers

179-182: Nucleotide sequences of DNA fragment

183: Nucleotide sequence of metF gene of Corynebacterium glutamicum 2256 (ATCC 13869)

184: Amino acid sequence of MetF protein of Corynebacterium glutamicum 2256 (ATCC 13869) 

The invention claimed is:
 1. A method for producing an objective substance, the method comprising: producing the objective substance by using a microorganism having an ability to produce the objective substance, wherein the microorganism has been modified so that the activity of an S-adenosylmethionine cycle enzyme is increased as compared with a non-modified microorganism, wherein the microorganism is a coryneform bacterium, wherein the S-adenosylmethionine cycle enzyme is a combination of methionine adenosyltransferase and 5,10-methylenetetrahydrofolate reductase, and optionally may include methionine synthase; and wherein the objective substance is selected from metabolites the biosynthesis of which requires S-adenosylmethionine selected from the group consisting of vanillin, vanillic acid, mugineic acid, ferulic acid, polyamine, guaiacol, 4-vinylguaiacol, 4-ethylguaiacol, creatine, and combinations thereof; wherein said producing comprises: cultivating the microorganism in a culture medium comprising a carbon source so that the objective substance is produced and accumulates in the culture medium, or converting a precursor of the objective substance into the objective substance by: cultivating the microorganism in a culture medium comprising the precursor so that the objective substance is produced and accumulates in the culture medium, or allowing cells of the microorganism to act on the precursor in a reaction mixture so that the objective substance is produced and accumulates in the reaction mixture.
 2. The method according to claim 1, wherein the cells are present in a culture broth of the microorganism, collected from a culture broth of the microorganism, present in a processed product of a culture broth of the microorganism, present in a processed product of the cells collected from a culture broth of the microorganism, or a combination thereof.
 3. The method according to claim 1, wherein the precursor is selected from the group consisting of protocatechuic acid, protocatechualdehyde, L-tryptophan, L-histidine, L-phenylalanine, L-tyrosine, L-arginine, L-ornithine, glycine, and combinations thereof.
 4. The method according to claim 1, the method further comprising collecting the objective substance.
 5. The method according to claim 1, wherein the methionine adenosyltransferase is encoded by an metK gene, the methionine synthase is encoded by an metH gene and/or an metE gene, and the 5,10-methylenetetrahydrofolate reductase is encoded by an metF gene.
 6. The method according to claim 5, wherein: the metK gene encodes a protein selected from the group consisting of: (1a) a protein comprising the amino acid sequence of SEQ ID NO: 162, (1b) a protein comprising the amino acid sequence of SEQ ID NO: 162 that includes substitution, deletion, insertion, and/or addition of 1 to 10 amino acid residues, and wherein said protein has methionine adenosyltransferase activity, and (1c) a protein comprising an amino acid sequence having an identity of 90% or higher to the amino acid sequence of SEQ ID NO: 162, and wherein said protein has methionine adenosyltransferase activity; the metH gene encodes a protein selected from the group consisting of: (2a) a protein comprising the amino acid sequence of SEQ ID NO: 168 or 170, (2b) a protein comprising the amino acid sequence of SEQ ID NO: 168 or 170 that includes substitution, deletion, insertion, and/or addition of 1 to 10 amino acid residues, and wherein said protein has methionine synthase activity, and (2c) a protein comprising an amino acid sequence having an identity of 90% or higher to the amino acid sequence of SEQ ID NO: 168 or 170, and wherein said protein has methionine synthase activity; the metE gene encodes a protein selected from the group consisting of: (3a) a protein comprising the amino acid sequence of SEQ ID NO: 166, (3b) a protein comprising the amino acid sequence of SEQ ID NO: 166 that includes substitution, deletion, insertion, and/or addition of 1 to 10 amino acid residues, and wherein said protein has methionine synthase activity, and (3c) a protein comprising an amino acid sequence showing an identity of 90% or higher to the amino acid sequence of SEQ ID NO: 166, and wherein said protein has methionine synthase activity; and the metF gene encodes a protein selected from the group consisting of: (4a) a protein comprising the amino acid sequence of SEQ ID NO: 172, 174, or 184, (4b) a protein comprising the amino acid sequence of SEQ ID NO: 172, 174, or 184 that includes substitution, deletion, insertion, and/or addition of 1 to 10 amino acid residues, and wherein said protein has 5,10-methylenetetrahydrofolate reductase activity, and (4c) a protein comprising an amino acid sequence having an identity of 90% or higher to the amino acid sequence of SEQ ID NO: 172, 174, or 184, and wherein said protein has 5,10-methylenetetrahydrofolate reductase activity.
 7. The method according to claim 1, wherein the activity of the S-adenosylmethionine cycle enzyme is increased by increasing the expression of a gene encoding the S-adenosylmethionine cycle enzyme.
 8. The method according to claim 7, wherein the expression of the gene encoding the S-adenosylmethionine cycle enzyme is increased by increasing the copy number of the gene and/or modifying an expression control sequence of the gene.
 9. The method according to claim 1, wherein the microorganism is a bacterium belonging to the genus Corynebacterium.
 10. The method according to claim 9, wherein the microorganism is Corynebacterium glutamicum.
 11. The method according to claim 1, wherein the microorganism has been further modified so that the activity of an enzyme that is involved in the biosynthesis of the objective substance is increased as compared with a non-modified microorganism.
 12. The method according to claim 11, wherein the enzyme that is involved in the biosynthesis of the objective substance is selected from the group consisting of 3-deoxy-D-arabino-heptulosonic acid 7-phosphate synthase, 3-dehydroquinate synthase, 3-dehydroquinate dehydratase, 3-dehydroshikimate dehydratase, O-methyltransferase, aromatic aldehyde oxidoreductase, and combinations thereof.
 13. The method according to claim 1, wherein the microorganism has been further modified so that the activity of phosphopantetheinyl transferase is increased as compared with a non-modified microorganism.
 14. The method according to claim 1, wherein the microorganism has been further modified so that the activity of an enzyme that is involved in the by-production of a substance other than the objective substance is reduced as compared with a non-modified microorganism.
 15. The method according to claim 14, wherein the enzyme that is involved in the by-production of a substance other than the objective substance is selected from the group consisting of vanillate demethylase, protocatechuate 3,4-dioxygenase, alcohol dehydrogenase, shikimate dehydrogenase, and combinations thereof.
 16. The method according to claim 1, wherein the microorganism has been further modified so that the activity of an L-cysteine biosynthesis enzyme is increased as compared with a non-modified microorganism.
 17. The method according to claim 16, wherein the L-cysteine biosynthesis enzyme is selected from the group consisting of proteins encoded by a cysI gene, cysX gene, cysH gene, cysD gene, cysN gene, cysY gene, cysZ gene, fpr2 gene, and combinations thereof.
 18. The method according to claim 16, wherein the activity of the L-cysteine biosynthesis enzyme is increased by increasing the activity of a protein encoded by a cysR gene.
 19. The method according to claim 1, wherein the microorganism has been further modified so that the activity of a protein encoded by an NCgl2048 gene is reduced as compared with a non-modified microorganism.
 20. The method according to claim 1, wherein the microorganism has been further modified so that the activity of enolase is reduced as compared with a non-modified microorganism.
 21. A method for producing vanillin, the method comprising: producing vanillic acid by the method according to claim 1; and converting said vanillic acid to vanillin. 